Polyplex gene delivery modulated by redox potential gradients

Polyplexes sensitive to redox potential gradients represent a promising class of vectors for delivery of nucleic acids. This review focuses on the recent advances in the development of these vectors. The biological rationale for the design of redox-sensitive polyplexes is discussed together with the basic synthetic approaches for introducing reducible disulfide bonds into the structure of the polyplexes. The biological properties of the redox-sensitive polyplexes of plasmid DNA, mRNA, antisense oligonucleotides and siRNA are reviewed with emphasis on in vitro cellular delivery, cytotoxicity and in vivo activity. Overall, redox-sensitive polyplexes represent a promising platform for further development as vectors for delivery of a wide variety of therapeutic nucleic acids.     

Effect of cell membrane thiols and reduction-triggered disassembly on transfection activity of bioreducible polyplexes

Bioreducible polyplexes are promising vectors for delivery of nucleic acids due to low toxicity and favorable transfection activity. The often improved transfection is usually explained by enhanced intracellular reductive disassembly of the polyplexes. This study evaluated the effect of enhanced reductive disassembly on transfection activity of plasmid DNA and antisense oligonucleotide (AON) polyplexes based on a series of bioreducible poly(amido amine)s (PAA). We found that the presence of disulfide bonds in PAA had no effect on nucleic acid binding, hydrodynamic size and zeta potential of polyplexes. Increasing the disulfide content in PAA increased susceptibility to reduction-triggered DNA and AON release from the polyplexes. Increasing the disulfide content in PAA increased DNA transfection but had no effect on AON transfection. Plasma membrane protein thiols played a key role in the observed enhancement of DNA transfection. The presence of disulfide bonds in PAA had no significant effect on the rate of intracellular DNA clearance, suggesting that enhanced intracellular disassembly of the bioreducible polyplexes is not a major contributing factor to the improved transfection activity.     

Decationized polyplexes for gene delivery

Gene therapy has received much attention in the field of drug delivery. Synthetic, nonviral gene delivery systems have gained increasing attention as vectors for gene therapy mainly due to a favorable immunogenicity profile and ease of manufacturing as compared to viral vectors. The great majority of these formulations are based on polycationic structures, due to their ability to interact with negatively charged nucleic acids to spontaneously form nanoparticles. In recent years, several polycationic systems have demonstrated high transfection in vitro. However, progress toward clinical applications has been slow, mainly because the cationic nature of these systems leads to intolerable toxicity levels, inappropriate biodistribution and unsatisfactory efficiency in vivo, particularly after systemic administration. Decationized polyplexes are a new class of gene delivery systems that have been developed as an alternative for conventional polycation-based systems. The major innovation introduced by decationized polyplexes is that these systems are based on neutral polymers, without any detrimental effect on the physicochemical stability or encapsulation ability, due to the transient presence of cationic charge and disulfide cross-links between the polymer chains by which the nucleic acids are physically entrapped in the particles. This editorial summarizes the most important features of decationized polyplexes and discusses potential implications for the development of new safe and efficient gene delivery systems.     

Nonviral approach for targeted nucleic acid delivery

Despite their relatively lower efficiency, nonviral approaches are emerging as safer alternatives in gene therapy to viral vectors. Delivery of nucleic acids to the target site is an important factor for effective gene expression (plasmid DNA) or knockdown (siRNA) with minimal side effects. Direct deposition at the target site by physical methods, including ultrasound, electroporation and gene gun, is one approach for local delivery. For less accessible sites, the development of carriers that can home into the target tissue is required. Cationic peptides, lipoplexes, polyplexes and nanoplexes have been used as carriers for delivery of nucleic acids. Targeting ligands, such as cell targeting peptides, have also been applied to decorate delivery vehicles in order to enhance their efficacy. This review focuses on delivery strategies and recent progress in non-viral carriers and their modifications to improve their performance in targeting and transfection.     

Antisense strategies and non-viral gene therapy for cancer

Effective gene therapy for cancer remains an elusive goal, even after more than a decade of intensive research. There has been, however, tremendous progress in the development of increasingly sophisticated non-viral (or synthetic) delivery vectors for local and systemic administration of nucleic acids. Recent clinical data has also indicated the feasibility of using antisense oligonucleotides to inhibit inappropriately expressed or mutated genes in human cancers. The purpose of this review is to provide an update of the patent literature on the development of non-viral approaches for cancer gene therapy. In particular, patents on lipoplexes and polyplexes for delivery of therapeutic genes and antisense oligonucleotides are reviewed. The diverse range of antisense strategies being developed and recent clinical data are also highlighted.     

Non-viral nucleic acid containing nanoparticles as cancer therapeutics

ABSTRACT

Introduction: The delivery of nucleic acids such as DNA and short interfering RNA (siRNA) is promising for the treatment of many diseases, including cancer, by enabling novel biological mechanisms of action. Non-viral nanoparticles are a promising class of nucleic acid carriers that can be designed to be safer and more versatile than traditional viral vectors.

Areas covered: In this review, recent advances in the intracellular delivery of DNA and siRNA are described with a focus on non-viral nanoparticle-based delivery methods. Material properties that have enabled successful delivery are discussed as well as applications that have directly been applied to cancer therapy. Strategies to co-deliver different nucleic acids are highlighted, as are novel targets for nucleic acid co-delivery.

Expert opinion: The treatment of complex genetically-based diseases such as cancer can be enabled by safe and effective intracellular delivery of multiple nucleic acids. Non-viral nanoparticles can be fabricated to deliver multiple nucleic acids to the same cell simultaneously to prevent tumor cells from easily compensating for the knockdown or overexpression of one genetic target. The continued innovation of new therapeutic modalities and non-viral nanotechnologies to provide target-specific and personalized forms of gene therapy hold promise for genetic medicine to treat diseases like cancer in the clinic.     

Dendrimers in gene delivery

Dendrimers have unique molecular architectures and properties that make them attractive materials for the development of nanomedicines. Key properties such as defined architecture and a high ratio of multivalent surface moieties to molecular volume also make these nanoscaled materials highly interesting for the development of synthetic (non-viral) vectors for therapeutic nucleic acids. Rational development of such vectors requires the link to be made between dendrimer structure and the morphology and physicochemistry of the respective nucleic acid complexes and, furthermore, to the biological performance of these systems at the cellular and systemic level. The review focuses on the current understanding of the role of dendrimers in those aspects of synthetic vector development. Dendrimer-based transfection agents have become routine tools for many molecular and cell biologists but therapeutic delivery of nucleic acids remains a challenge.     

Localized,non-viral delivery of nucleic acids: Opportunities,challenges and current strategies

Localized delivery of drugs is an emerging field both with regards to drug delivery during disease as well as in tissue engineering. Despite significant achievements made in the last decades, the efficient delivery of proteins and peptides remains challenging, especially in cases requiring long-term release of proteins after application. The localized delivery of nucleic acids (NA) represents an interesting alternative due to higher physicochemical stability of NA, increased efficiency by harnessing cells as bioreactors for the production of required proteins and improved versatility with regards to expression of specific proteins through plasmid DNA or repression of gene products through siRNA. However, unlike most proteins and peptides, NA must be delivered to the cytoplasm or nucleus to be efficacious, resulting in significant delivery challenges. We herein describe frequently used non-viral vectors for the delivery of NA including polyplexes, lipoplexes and lipopolyplexes and summarize recent developments in the field of nucleic acid delivery systems for local application based on hydrogels, solid scaffolds and physical delivery methods. The challenges associated with the different approaches are identified and options to address these challenges are discussed.     

Nucleic acid based therapeutics for tumor therapy

Although being a heterogeneous disease, cancer has certain characteristic features which can be utilized for treatment with novel macromolecular therapeutics. The active cycling status of tumor cells, proliferating tumor endothelium and a leaky vasculature allow the targeted delivery of therapeutically active nucleic acids into tumor tissue. We and others have developed polycationic gene carriers forming so called polyplexes with nucleic acids. Cellular aspects like binding, internalization and intracellular fate were enlightened. Additionally, virus like domains were incorporated into the polyplex. Hydrophilic shielding domains protect the polyplex from unspecific interaction with blood components, targeting ligands allow cell specific binding and internalization into target cells, and membrane active peptides have a favorable influence on intracellular trafficking. Physical targeting of polyplexes, like locoregional hyperthermia and photochemical internalization (PCI) have been further used to enhance the efficiency of nucleic acid transfer. Therapeutic concepts were carried out in different tumor models in mice. Local application of synthetic, double stranded RNA led to eradication of intracranial glioblastoma. A gene directed enzyme prodrug approach utilizing site directed activation of cyclophosphamide with cytochrome P450 gave first, promising results.     

CLINICAL TRIALS AND TRANSLATIONAL MEDICINE COMMENTARY: Drug Delivery Trends in Clinical Trials and Translational Medicine: Challenges and Opportunities in the Delivery of Nucleic Acid-Based Therapeutics

The ability to deliver nucleic acids (e.g., plasmid DNA, antisense oligonucleotides, siRNA) offers the potential to develop potent vaccines and novel therapeutics. However, nucleic acid-based therapeutics are still in their early stages as a new category of biologics. The efficacy of nucleic acids requires that these molecules be delivered to the interior of the target cell, which greatly complicates delivery strategies and compromises efficiency. Due to the safety concerns of viral vectors, synthetic vectors such as liposomes and polymers are preferred for the delivery of nucleic acid-based therapeutics. Yet, delivery efficiencies of synthetic vectors in the clinic are still too low to obtain therapeutic levels of gene expression. In this review, we focus on some key issues in the field of nucleic acid delivery such as PEGylation, encapsulation and targeted delivery and provide some perspectives for consideration in the development of improved synthetic vectors.     

Chemical vectors for gene delivery: a current review on polymers, peptides and lipids containing histidine or imidazole as nucleic acids carriers

DNA/cationic lipid (lipoplexes), DNA/cationic polymer (polyplexes) and DNA/cationic polymer/cationic lipid (lipopolyplexes) electrostatic complexes are proposed as non-viral nucleic acids delivery systems. These DNA-nanoparticles are taken up by the cells through endocytosis processes, but the low capacity of DNA to escape from endosomes is regarded as the major limitations of their transfection efficiency. Here, we present a current report on a particular class of carriers including the polymers, peptides and lipids, which is based on the exploitation of the imidazole ring as an endosome destabilization device to favour the nucleic acids delivery in the cytosol. The imidazole ring of histidine is a weak base that has the ability to acquire a cationic charge when the pH of the environment drops bellow 6. As it has been demonstrated for poly(histidine), this phenomena can induce membrane fusion and/or membrane permeation in an acidic medium. Moreover, the accumulation of histidine residues inside acidic vesicles can induce a proton sponge effect, which increases their osmolarity and their swelling. The proof of concept has been shown with polylysine partially substituted with histidine residues that has caused a dramatic increase by 3–4.5 orders of magnitude of the transfection efficiency of DNA/polylysine polyplexes. Then, several histidine-rich polymers and peptides as well as lipids with imidazole, imidazolinium or imidazolium polar head have been reported to be efficient carriers to deliver nucleic acids including genes, mRNA or SiRNA in vitro and in vivo. More remarkable, histidylated carriers are often weakly cytotoxic, making them promising chemical vectors for nucleic acids delivery.This article is part of a themed section on Vector Design and Drug Delivery. For a list of all articles in this section see the end of this paper, or visit: http://www3.interscience.wiley.com/journal/121548564/issueyear?year=2009     

Uptake and intracellular fate of multifunctional nanoparticles: a comparison between lipoplexes and polyplexes via quantum dot mediated Förster resonance energy transfer

Lipoplexes and polyplexes represent the two major nanocarrier systems for nucleic acid delivery. Previous studies examining their uptake and intracellular unpacking rely on organic fluorophores fraught with low signal intensity and photobleaching. In this work quantum dot mediated F?rster resonance energy transfer (QD-FRET) was first used to study and compare the cellular uptake and the intracellular fate of oligodeoxynucelotide (ODN)-based lipoplexes and polyplexes. QD605-amine and Cy5-labeled ODN (Cy5-GTI2040) were chosen as the FRET pair. By adjusting the lipid/ODN ratio of lipoplexes and the nitrogen/phosphate (N/P) ratio of polyplexes, lipoplexes and polyplexes with comparable physical properties were produced. The biological activities of dual-labeled lipoplexes and polyplexes remained unaltered compared to their unlabeled counterparts as evidenced by their comparable antisense activities against protein R2 in KB cells. Flow cytometry and confocal microscopy revealed similar pattern of uptake for these two types of nanoparticles, although polyplexes had a higher dissociation rate than lipoplexes in KB cells. We demonstrate that QD-FRET is a sensitive tool to study the uptake and intracellular unpacking of lipoplexes and polyplexes, which may help optimize their formulations for various theranostics applications.     

Polycation gene delivery systems: escape from endosomes to cytosol

Clinical success of gene therapy based on oligonucleotides (ODNs), ribozymes, RNA and DNA will be greatly dependent on the availability of effective delivery systems. Polycations have gained increasing attention as a non-viral gene delivery vector in the past decades. Significant progress has been made in understanding complex formation between polycations and nucleic acids, entry of the complex into the cells and subsequent entry into the nucleus. Sophisticated molecular architectures of cationic polymers have made the vectors more stable and less susceptible to binding by enzymes or proteins. Incorporation of specific ligands to polycations has resulted in more cell-specific uptake by receptor-mediated mechanisms. However, there are still other barriers limiting the transfection efficiency of polycation gene delivery systems. There is a consensus that polycation-DNA complexes (polyplexes) enter cells via the endocytotic pathway. It is not clearly understood, however, how the polyplexes escape (if they do) from endosomes, how DNA is released from the polyplexes or how the released DNA is expressed. The primary focus of this article is to review various polycation gene delivery systems, which are designed to translocate DNA from endosomes into cytosol. Many polycation gene delivery systems have tried to mimic the mechanisms that viruses use for the endosomal escape. Polycation gene delivery systems are usually coupled with synthetic amphipathic peptides mimicking viral fusogenic peptides, histidine-based gene delivery systems for pH-responsive endosomal escape, polycations with intrinsic endosomolytic activity by the proton sponge mechanism and polyanions to mimic the anionic amphiphilic peptides.     

Bioresponsive polyplexes – chemically programmed for nucleic acid delivery

ABSTRACT

Introduction: The whole delivery process of nucleic acids is very challenging. Appropriate carrier systems are needed, which show extracellular stability and intracellular disassembly. Viruses have developed various strategies to meet these requirements, as they are optimized by biological evolution to transfer genetic information into host cells. Taking viruses as models, smart synthetic carriers can be designed, mimicking the efficient delivery process of viral infection. These ‘synthetic viruses’ are pre-programmed and respond to little differences in their microenvironment, caused by either exogenous or endogenous stimuli.

Areas covered: This review deals with polymer-based, bioresponsive nanosystems (polyplexes) for the delivery of nucleic acids. Strategies utilizing pH-responsiveness, redox-responsiveness as well as sensitivity towards enzymes will be described more in detail. Systems, which respond to other endogenous triggers (i.e. reactive oxygen species, adenosine triphosphate, hypoxia), will be briefly illustrated. Moreover, some examples for combined bioresponsiveness will be presented.

Expert opinion: Bioresponsive polyplexes are a smart way to facilitate programmed, timely delivery of nucleic acids to desired, specific sites. Nevertheless, further optimization is necessary to improve the still moderate transfection efficiency and specificity – also in regard to medical translation. For this purpose, precise carrier structures are desirable and stability issues of bioresponsive systems must be considered.     

Cell-penetrating peptides for the delivery of nucleic acids

INTRODUCTION: Different gene therapy approaches have gained extensive interest lately and, after many initial hurdles, several promising approaches have reached to the clinics. Successful implementation of gene therapy is heavily relying on finding efficient measures to deliver genetic material to cells. Recently, non-viral delivery of nucleic acids and their analogs has gained significant interest. Among non-viral vectors, cell-penetrating peptides (CPPs) have been extensively used for the delivery of nucleic acids both in vitro and in vivo. AREAS COVERED: In this review we will discuss recent advances of CPP-mediated delivery of nucleic acid-based cargo, concentrating on the delivery of plasmid DNA, splice-correcting ONs, and small-interfering RNAs. EXPERT OPINION: CPPs have proved their potential as carriers for nucleic acids. However, similarly to other non-viral vectors, CPPs require further development, as efficient systemic delivery is still seldom achieved. To achieve this, CPPs should be modified with entities that would allow better endosomal escape, targeting of specific tissues and cells, and shielding agents that increase the half-life of the vehicles. Finally, to understand the clinical potential of CPPs, they require more thorough investigations in clinically relevant disease models and in pre-clinical and clinical studies.     

Cell-penetrating peptides for the delivery of nucleic acids

Introduction: Different gene therapy approaches have gained extensive interest lately and, after many initial hurdles, several promising approaches have reached to the clinics. Successful implementation of gene therapy is heavily relying on finding efficient measures to deliver genetic material to cells. Recently, non-viral delivery of nucleic acids and their analogs has gained significant interest. Among non-viral vectors, cell-penetrating peptides (CPPs) have been extensively used for the delivery of nucleic acids both in vitro and in vivo.

Areas covered: In this review we will discuss recent advances of CPP-mediated delivery of nucleic acid-based cargo, concentrating on the delivery of plasmid DNA, splice-correcting ONs, and small-interfering RNAs.

Expert opinion: CPPs have proved their potential as carriers for nucleic acids. However, similarly to other non-viral vectors, CPPs require further development, as efficient systemic delivery is still seldom achieved. To achieve this, CPPs should be modified with entities that would allow better endosomal escape, targeting of specific tissues and cells, and shielding agents that increase the half-life of the vehicles. Finally, to understand the clinical potential of CPPs, they require more thorough investigations in clinically relevant disease models and in pre-clinical and clinical studies.     

Complexity in the therapeutic delivery of RNAi medicines: an analytical challenge

Introduction: Nucleic acids have witnessed a dramatic acceleration in their therapeutic exploitation and currently represent a growing number of applications in drug development pipelines. However, a more wide-spread development of therapeutics based on nucleic acids is restricted by their poor chemical and enzymatic stability in vivo, lack of cellular uptake and insufficient capability to reach intracellular targets.

Areas covered: Advanced formulation of nucleic acids in nano-sized carriers may help unlocking their potential as therapeutic agents. Nano-sized matters own specific features responsible for inducing characteristic interactions with biological molecules and tissues. These properties enable for the enhancement of the nano-formulation’s therapeutic efficacy, but on the other hand, the nanomatters interactions in biological fluids are also responsible for adverse effects. The purpose of this review is to reflect on the complexity in the therapeutic delivery of RNA interference-based drugs emerging from the recent clinical experiences and report the actual technological and analytical advances introduced to solve it.

Expert opinion: The complexity in the therapeutic delivery of nucleic acids and the heterogeneity of side effects make the interpretation of the therapeutic outcome difficult. Hence the development of analytical approaches applicable in the field of nucleic acid delivery is becoming a major challenge.     

Gene silencing activity of siRNA polyplexes based on biodegradable polymers

Cationic polymers are used as non-viral vectors for nucleic acid delivery. In this study, two biodegradable cationic polymers were evaluated for the purpose of siRNA delivery: pHPMA-MPPM (poly((2-hydroxypropyl) methacrylamide 1-methyl-2-piperidine methanol)) and TMC (O-methyl-free N,N,N-trimethylated chitosan). The silencing activity and the cellular cytotoxicity of polyplexes based on these biodegradable polymers were compared with those based on non-biodegradable pDMAEMA (poly(2-dimethylamino)ethyl methacrylate) and PEI (polyethylenimine) and with the regularly used lipidic transfection agent Lipofectamine. To promote endosomal escape, either the endosomolytic peptide diINF-7 was added to the formulations or photochemical internalization (PCI) was applied. Incubation of H1299 human lung cancer cells expressing firefly luciferase with polyplexes based on pHPMA-MPPM and TMC showed 30-40% silencing efficiency. This silencing activity was equal to or better than that obtained with the standard transfectants. Under all experimental conditions tested, the cytotoxicity of the biodegradable polymers was low. The application of PCI, as well as the addition of the diINF-7 peptide to the formulations increased their silencing activity up to 70-80%. This demonstrates that pHPMA-MPPM- and TMC-based polyplexes benefit substantially from endosomal escape enhancement. Importantly, the polyplexes retained their silencing activity in the presence of serum, and they showed low cytotoxicity. These biodegradable vectors are therefore attractive systems for further in vivo evaluations.     

Chemically modified cell-penetrating peptides for the delivery of nucleic acids

Short nucleic acids targeting biologically important RNAs and plasmids have been shown to be promising future therapeutics; however, their hydrophilic nature greatly limits their utility in clinics and therefore efficient delivery vectors are greatly needed. Cell-penetrating peptides (CPPs) are relatively short amphipathic and/or cationic peptides that are able to transport various biologically active molecules inside mammalian cells, both in vitro and in vivo, in a seemingly non-toxic fashion. Although CPPs have proved to be appealing drug delivery vehicles, their major limitation in nucleic acid delivery is that most of the internalized peptide-cargo is entrapped in endosomal compartments following endocytosis and the bioavailability is therefore severely reduced. Several groups are working towards overcoming this obstacle and this review highlights the evidence that by introducing chemical modification in CPPs, the bioavailability of delivered nucleic acids increases significantly.     

Hepatocyte targeting of nucleic acid complexes and liposomes by a T7 phage p17 peptide

A critical step for liver-directed gene therapy is the selective targeting of nucleic acids to hepatocytes. We have previously discovered that the proximal half of the T7 phage tail fiber protein (p17) targeted intact T7 phage and recombinant proteins to hepatocytes in vivo. In the present study, we have localized the targeting activities to a 33 amino acid sequence within the p17 coiled-coil rod domain. Given that the tail fiber domain from which the peptide was derived may form alpha and triple helical structures, biophysical studies (CD spectra and analytical ultracentrifugation) were conducted to determine the secondary and tertiary structures of the peptide. This peptide is able to target proteins, polymers, and siRNA and also particles such as DNA polyplexes and liposomes to hepatocytes. A variety of coupling strategies and chemistries were employed, thus demonstrating that this peptide is a versatile system for delivering cargo. The ability of this hepatocyte-targeting peptide to target DNA-containing particles suggests that it should be useful in the development of both nonviral and viral vectors. However, biological function of delivered cargo has not been demonstrated. This was primarily due to failure of delivered cargo to escape the endosomes. Further studies are in progress to provide functional activity of delivered nucleic acids by enabling their endosomal escape.