Cellular uptake and intracellular trafficking of antisense and siRNA oligonucleotides

Significant progress is being made concerning the development of oligonucleotides as therapeutic agents. Studies with antisense, siRNA, and other forms of oligonucleotides have shown promise in cellular and animal models and in some clinical studies. Nonetheless, our understanding of how oligonucleotides function in cells and tissues is really quite limited. One major issue concerns the modes of uptake and intracellular trafficking of oligonucleotides, whether as "free" molecules or linked to various delivery moieties such as nanoparticles or targeting ligands. In this review, we examine the recent literature on oligonucleotide internalization and subcellular trafficking in the context of current insights into the basic machinery for endocytosis and intracellular vesicular traffic.     

Cellular delivery of impermeable effector molecules in the form of conjugates with peptides capable of mediating membrane translocation.

Most molecules that are not actively imported by living cells are impermeable to cell membranes, including practically all macromolecules and even many small molecules whose physicochemical properties prevent passive membrane diffusion. The use of peptide vectors capable of transporting such molecules into cells in the form of covalent conjugates has become an increasingly attractive solution to this problem. Not only has this technology permitted the study of modulating intracellular target proteins, but it has also gained importance as an alternative to conventional cellular transfection with oligonucleotides. Peptide vectors derived from viral, bacterial, insect, and mammalian proteins endowed with membrane translocation properties have now been proposed as delivery vectors. These are discussed comprehensively and critically in terms of relative utility, applications to compound classes and specific molecules, and relevant conjugation chemistry. Although in most cases the mechanisms of membrane translocation are still unclear, physicochemical studies have been carried out with a number of peptide delivery vectors. Unifying and distinguishing mechanistic features of the various vectors are discussed. Until a few years ago speculations that it might be possible to deliver peptides, proteins, oligonucleotides, and impermeable small molecules with the aid of cellular delivery peptides not only to target cells in vitro, but in vivo, was received with scepticism. However, the first studies showing pharmacological applications of conjugates between macromolecules and peptide delivery vectors are now being reported, and therapies based on such conjugates are beginning to appear feasible.     

Protein transduction domain delivery of therapeutic macromolecules

Owing to their unprecedented selectivity, specific activity and potential for 1000+ fold amplification of signal, macromolecules, such as peptides, catalytic protein domains, complete proteins, and oligonucleotides, offer great potential as therapeutic molecules. However, therapeutic use of macromolecules is limited by their poor penetration in tissues and their inability to cross the cellular membrane. The discovery of small cationic peptides that cross the membrane, called Protein Transduction Domains (PTDs) or Cell Penetrating Peptides (CPPs), in the late 1980s opened the door to cellular delivery of large, bioactive molecules. Now, PTDs are widely used as research tools, and impressively, multiple clinical trials are testing PTD-mediated delivery of macromolecular drug conjugates in patients with a variety of diseases.     

Cellular uptake and intracellular fate of antisense oligonucleotides

Antisense oligonucleotides with sequences complementary to a given genetic target can enter cells in sufficient quantities to selectively inhibit gene expression. Thus, they have a potential therapeutic use in preventing undesirable gene expression in diseases such as cancer and AIDS. However, it is remarkable that these molecules, which have high molecular weights and are often charged, gain entry to cells at all. In this article, we review the possible mechanisms by which oligonucleotides enter cells and their subsequent intracellular fates. We also discuss current approaches for improving cellular uptake and delivery of antisense nucleic acids to their intended targets.     

Facile synthesis,optical and conformational characteristics,and efficient intracellular delivery of a peptide–DNA conjugate

Covalent conjugation of disparate peptide and oligonucleotide biomacromolecular species produces peptide–oligonucleotide conjugates (POCs), which are interesting molecules with great potential for use in diverse bioapplications. However, peptide–oligonucleotide conjugation methods are not well established, and the intracellular delivery efficacy of POCs is debatable. Here, we describe a simple method for the synthesis and purification of POCs. When peptides are carefully designed to have a near-neutral charge state, a relatively hydrophobic polarity, and receptor-targeting ligands, synthesis and purification become highly efficient and straightforward. UV–vis, fluorescence, and circular dichroism studies show that both types of molecules mutually influence each other, changing their optical and conformational characteristics in the context of POCs. The combined effect of peptide design strategy, targeting ligands, and relatively hydrophobic property, enables the efficient cellular delivery of POCs.     

Cellular delivery and biological activity of antisense oligonucleotides conjugated to a targeted protein carrier

Targeted delivery can potentially improve the pharmacological effects of antisense and siRNA oligonucleotides. Here, we describe a novel bioconjugation approach to the delivery of splice-shifting antisense oligonucleotides (SSOs). The SSOs are linked to albumin via reversible S-S bonds. The albumin is also conjugated with poly(ethylene glycol) (PEG) chains that terminate in an RGD ligand that selectively binds the alphavbeta3 integrin. As a test system, we utilized human melanoma cells that express the alphavbeta3 integrin and that also contain a luciferase reporter gene that can be induced by delivery of SSOs to the cell nucleus. The RGD-PEG-SSO-albumin conjugates were endocytosed by the cells in an RGD-dependent manner; using confocal fluorescence microscopy, evidence was obtained that the SSOs accumulate in the nucleus. The conjugates were able to robustly induce luciferase expression at concentrations in the 25-200 nM range. At these levels, little short-term or long-term toxicity was observed. Thus, the RGD-PEG-albumin conjugates may provide an effective tool for targeted delivery of oligonucleotides to certain cells and tissues.     

Synthesis and applications of oligonucleotide-carbohydrate conjugates

Nowadays, oligonucleotide-carbohydrate conjugates are used in antisense biotechnology and in the study of glycosylated DNA functioning in vitro. The application of mono- and disaccharide phosphoramidites, solid-phase supports with immobilized carbohydrates, glycosylated nucleoside phosphoramidites, and postsynthetic conjugation of reactive sugar derivatives with oligonucleotides for preparation of oligonucleotide-carbohydrate conjugates have been systematically studied. The advantages and disadvantages of these approaches are considered. Possible strategies for synthesis of glycoclusters with different topologies conjugated to DNA are discussed. Applications of oligonucleotide-carbohydrate conjugates are highlighted. Studies of interactions of glycosylated oligonucleotides with proteins and effective cell-specific delivery of oligonucleotide-carbohydrate conjugates are discussed.     

Tat-conjugated synthetic macromolecules facilitate cytoplasmic drug delivery to human ovarian carcinoma cells

We have synthesized N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer-cell penetrating peptide Tat conjugates and evaluated their subcellular distribution in A2780 human ovarian carcinoma cells by confocal fluorescence microscopy and subcellular fractionation. Our data indicate the transport of these conjugates by a single Tat molecule to both the cytoplasm and nucleus via a nonendocytotic and concentration independent process. The uptake was observed to occur within 3 min, as confirmed by live cell microscopy. In contrast, HPMA copolymers lacking the Tat peptide were internalized solely by endocytosis. For the first time, Tat-mediated cytoplasmic delivery of a polymer bound anticancer drug, doxorubicin, was also demonstrated. These findings establish the feasibility of overcoming major cellular and subcellular obstacles to intracellular macromolecular delivery and hold great promise for the development of polymer-based systems for the cytoplasmic delivery of therapeutic molecules.     

In situ entry of oligonucleotides into brain cells can occur through a nucleic acid channel

Brain tissue has become a challenging therapeutic target, in part because of failure of conventional treatments of brain tumors and a gradually increasing number of neurodegenerative diseases. Because antisense oligonucleotides are readily internalized by neuronal cells in culture, these compounds could possibly serve as novel therapeutic agents to meet such a challenge. In previous in vitro work using cell culture systems, we have demonstrated that intracellular delivery requires a vector such as cationic liposomes since free oligonucleotides remain largely trapped in the endocytic pathway following cellular uptake. Here we studied the cellular uptake properties of oligonucleotides by explants of rat brain (brain slices), and by in vivo brain tissue after administration of oligonucleotides by bolus injection. In contrast to in vitro uptake, we show that in brain slices oligonucleotides were taken up by neuronal and nonneuronal cells, irrespective of their assembly with cationic liposomes. In either case, a diffuse distribution of oligonucleotides was seen in the cytosol and/or nucleus. Uptake of oligonucleotides by brain slices as a result of membrane damage, potentially arising from the isolation procedure, could be excluded. Interestingly, internalization was inhibited following treatment of the tissue with antibody GN-2640, directed against a nucleic acid channel, present in rat kidney cells. Our data support the view that an analogous channel is present in brain tissue, allowing entry of free oligonucleotides but not plasmids. Indeed, for delivery of the latter and accomplishment of effective transfection, cationic lipids were needed for gene translocation into both brain slices and brain tissue in vivo. These data imply that for antisense therapy to become effective in brain, cationic lipid-mediated delivery will only be needed for specific cell targeting but not necessarily for delivery per se to accomplish nuclear deposition of oligonucleotides into brain cells and subsequent down-regulation of disease-related targets.     

Lipid-modified oligonucleotide conjugates: Insights into gene silencing,interaction with model membranes and cellular uptake mechanisms

The ability of oligonucleotides to silence specific genes or inhibit the biological activity of specific proteins has generated great interest in their use as research tools and therapeutic agents. Unfortunately, their biological applications meet the limitation of their poor cellular accessibility. Developing an appropriate delivery system for oligonucleotides is essential to achieve their efficient cellular uptake. In the present work a series of phosphorothioate lipid–oligonucleotide hybrids were synthesized introducing covalently single or double lipid tails at both 3′- and 5′-termini of an antisense oligonucleotide. Gene transfections in cultured cells showed antisense luciferase inhibition without the use of a transfecting agent for conjugates modified with the double-lipid tail at 5′-termini. The effect of the double lipid-tailed modification was further studied in detail in several model membrane systems as well as in cellular uptake experiments. During these studies the spontaneous formation of self-assembled microstructures is clearly observed. Lipidation allowed the efficient incorporation of the oligonucleotide in HeLa cells by a macropinocytosis mechanism without causing cytotoxicity in cells or altering the binding properties of the oligonucleotide conjugates. In addition, both single- and double-tailed compounds showed a similar behavior in lipid model membranes, making them useful in nucleotide-based technologies.     

Targeting the HIV-1 RNA leader sequence with synthetic oligonucleotides and siRNA: chemistry and cell delivery

New candidates for development as potential drugs or virucides against HIV-1 infection and AIDS continue to be needed. The HIV-1 RNA leader sequence has many essential functional sites for virus replication and regulation that includes several highly conserved sequences. The review describes the historical context of targeting the HIV-1 RNA leader sequence with antisense phosphorothioate oligonucleotides, such as GEM 91, and goes on to describe modern approaches to targeting this region with steric blocking oligonucleotide analogues having newer and more advantageous chemistries, as well as recent studies on siRNA, towards the attainment of antiviral activity. Recent attempts to obtain improved cell delivery are highlighted, including exciting new developments in the use of peptide conjugates of peptide nucleic acid (PNA) as potential virucides.     

Targeting the HIV-1 RNA leader sequence with synthetic oligonucleotides and siRNA: Chemistry and cell delivery

New candidates for development as potential drugs or virucides against HIV-1 infection and AIDS continue to be needed. The HIV-1 RNA leader sequence has many essential functional sites for virus replication and regulation that includes several highly conserved sequences. The review describes the historical context of targeting the HIV-1 RNA leader sequence with antisense phosphorothioate oligonucleotides, such as GEM 91, and goes on to describe modern approaches to targeting this region with steric blocking oligonucleotide analogues having newer and more advantageous chemistries, as well as recent studies on siRNA, towards the attainment of antiviral activity. Recent attempts to obtain improved cell delivery are highlighted, including exciting new developments in the use of peptide conjugates of peptide nucleic acid (PNA) as potential virucides.     

Folate and folate-PEG-PAMAM dendrimers: synthesis, characterization, and targeted anticancer drug delivery potential in tumor bearing mice

Ligand-mediated targeting of drugs especially in anticancer drug delivery is an effective approach. Dendrimers, due to unique surface topologies, can be a choice in this context. In the present study, PAMAM (polyamidoamine) dendrimers up to fourth generation were synthesized and characterized through infrared (IR), nuclear magnetic resonance (NMR), electrospray ionization (ESI) mass spectrometric, and transmission electron microscopic (TEM) techniques. Primary amines present on the dendritic surface were conjugated through folic acid and folic acid-PEG (poly(ethylene glycol))-NHS (N-hydroxysuccinimide) conjugates. Tumor in mice was induced through the use of KB cell culture. Prepared dendritic conjugates were evaluated for the anticancer drug delivery potential using 5-FU (5-fluorouracil) in tumor-bearing mice. Approximately 31% of 5-FU was loaded in folate-PEG-dendritic conjugates. Results indicated that folate-PEG-dendrimer conjugate was significantly safe and effective in tumor targeting compared to a non-PEGylated formulation. Tailoring of dendrimers via PEG-folic acid reduced hemolytic toxicity, which led to a sustained drug release pattern as well as highest accumulation in the tumor area.     

Efficient cellular delivery of β-galactosidase mediated by NrTPs, a new family of cell-penetrating peptides

Nucleolar targeting peptides (NrTPs), a recently developed family of cell-penetrating peptides, have been shown to be very efficient in entering cells and accumulating in their nucleoli. In this work, we have used conjugates of NrTP6 (YKQSHKKGGKKGSG) covalently linked to β-galactosidase in order to demonstrate the capacity of NrTP for intracellular delivery of large molecules. NrTP6/β-galactosidase conjugates, prepared by maleimide-based chemistry, were stable and enzymatically active on the standard 4-methylumbelliferyl β-d-galactopyranoside substrate. Their translocation into HeLa cells, monitored by β-galactosidase activity as a readout of the uptake, showed efficient cellular entry and thus demonstrated the potential of NrTPs for intracellular delivery of large-size cargos with preservation of biological activity.     

Mechanisms and optimization of in vivo delivery of lipophilic siRNAs

Cholesterol-conjugated siRNAs can silence gene expression in vivo. Here we synthesize a variety of lipophilic siRNAs and use them to elucidate the requirements for siRNA delivery in vivo. We show that conjugation to bile acids and long-chain fatty acids, in addition to cholesterol, mediates siRNA uptake into cells and gene silencing in vivo. Efficient and selective uptake of these siRNA conjugates depends on interactions with lipoprotein particles, lipoprotein receptors and transmembrane proteins. High-density lipoprotein (HDL) directs siRNA delivery into liver, gut, kidney and steroidogenic organs, whereas low-density lipoprotein (LDL) targets siRNA primarily to the liver. LDL-receptor expression is essential for siRNA delivery by LDL particles, and SR-BI receptor expression is required for uptake of HDL-bound siRNAs. Cellular uptake also requires the mammalian homolog of the Caenorhabditis elegans transmembrane protein Sid1. Our results demonstrate that conjugation to lipophilic molecules enables effective siRNA uptake through a common mechanism that can be exploited to optimize therapeutic siRNA delivery.     

Peptide conjugates for chromosomal gene targeting by triplex-forming oligonucleotides

Triplex-forming oligonucleotides (TFOs) are DNA-binding molecules, which offer the potential to selectively modulate gene expression. However, the biological activity of TFOs as potential antigene compounds has been limited by cellular uptake. Here, we investigate the effect of cell-penetrating peptides on the biological activity of TFOs as measured in an assay for gene-targeted mutagenesis. Using the transport peptide derived from the third helix of the homeodomain of antennapedia (Antp), we tested TFO–peptide conjugates compared with unmodified TFOs. TFOs covalently linked to Antp resulted in a 20-fold increase in mutation frequency when compared with ‘naked’ oligonucleotides. There was no increase above background in mutation frequency when Antp by itself was added to the cells or when Antp was linked to mixed or scrambled sequence control oligonucleotides. In addition, the TFO–peptide conjugates increased the mutation frequency of the target gene, and not the control gene, in a dose-responsive manner. Confocal microscopy using labeled oligonucleotides indicated increased cellular uptake of TFOs when linked to Antp, consistent with the gene-targeting data. These results suggest that peptide conjugation may enhance intranuclear delivery of reagents designed to bind to chromosomal DNA.     

In vivo generation of highly abundant sequence-specific oligonucleotides for antisense and triplex gene regulation.

Antisense and triplex oligonucleotides continue to demonstrate potential as mediators of gene-specific repression of protein synthesis. However, inefficient and heterogeneous cellular uptake, intracellular sequestration, and rapid intracellular and extracellular degradation represent obstacles to their eventual clinical utility. Efficient cellular delivery of targeted ribozymes can present similar problems. In this report we describe a system for circumventing these obstacles and producing large quantities of short, sequence-specific RNA oligonucleotides for use in these gene regulation strategies. The oligonucleotides are generated from a vector containing promoter, capping, and termination sequences from the human small nuclear U6 gene, surrounding a synthetic sequence incorporating the oligonucleotide of interest. In vivo, these oligonucleotides are produced constitutively and without cell type specificity in levels up to 5 x 10(6) copies per cell, reach steady-state levels of expression within 9 hours post-transfection, and are still readily detectable 7 days post-transfection. In addition, these oligonucleotides are retained in the nucleus, obtain a 5' gamma-monomethyl phosphate cap, and have an intracellular half-life of approximately one hour. This expression vector provides a novel and efficient method of intracellular delivery of antisense or triplex RNA oligonucleotides (and/or ribozymes) for gene regulation, as well as a cost-effective means of comparing the biological activity arising from a variety of different potential oligonucleotide sequences.     

核酸治疗的靶向性传递

寡核苷酸包括反义核酸和干扰RNA等,它们能够为多种疾病提供快速、特异性的治疗,具有很高的应用潜力。然而这些分子能否有效地传递到特定的细胞和组织对于最终的临床应用非常关键。靶向性的传递能够提高寡核苷酸药物的特异性和使用效率,使药物分子能有效到达作用位点,进而发挥它们的治疗效果。一些基于不同平台的靶向性配体传递策略已经形成,并能够很好的发挥其生物学活性。本文针对当前该研究领域的进展提供一个概述。