Allergic asthma is one of the leading chronic lung diseases of both children and adults worldwide, resulting in significant morbidity and mortality in affected individuals. Many patients have severe asthma, which is refractory to treatment, illustrating the need for the development of new therapeutics for this disease. Herein, we describe the use of a peptide cross-linked nucleic acid nanocapsule (NAN) for the delivery of a GATA3-specific DNAzyme to immune cells, with demonstration of modulated transcriptional activity and behavior of those cells. The NAN, built from peptide cross-linked surfactants, is chemically designed to degrade under inflammation conditions releasing individual DNAzyme-surfactant conjugates in response to proteolytic enzymes. Using the NAN, GATA3 DNAzymes were delivered efficiently to human peripheral blood mononuclear cells, with clear evidence of uptake by CD4+ helper T cells without the need for harsh transfection agents. Knockdown of GATA3 was achieved in vitro using human Jurkat T cells, which express GATA3 under homeostatic conditions. Additionally, mice treated with DNAzyme-NANs during house dust mite (HDM)-induced asthma developed less severe allergic lung inflammation than HDM-only control mice, as measured by pulmonary eosinophilia. This study suggests that peptide cross-linked GATA3 DNAzyme-NANs may have the potential to decrease the severity of asthma symptoms in human patients, and development of this technology for human use warrants further investigation.
Therapeutic nucleic acids hold immense potential in combating undruggable, gene-based diseases owing to their high programmability and relative ease of synthesis. While the delivery of this class of therapeutics has successfully entered the clinical setting, extrahepatic targeting, endosomal escape efficiency, and subcellular localization. On the other hand, viruses serve as natural carriers of nucleic acids and have acquired a plethora of structures and mechanisms that confer remarkable transfection efficiency. Thus, understanding the structure and mechanism of viruses can guide the design of synthetic nucleic acid vectors. This review revisits relevant structural and mechanistic features of viruses as design considerations for efficient nucleic acid delivery systems. This article explores how viral ligand display and a metastable structure are central to the molecular mechanisms of attachment, entry, and viral genome release. For comparison, accounted for are details on the design and intracellular fate of existing nucleic acid carriers and nanostructures that share similar and essential features to viruses. The review, thus, highlights unifying themes of viruses and nucleic acid delivery systems such as genome protection, target specificity, and controlled release. Sophisticated viral mechanisms that are yet to be exploited in oligonucleotide delivery are also identified as they could further the development of next-generation nonviral nucleic acid vectors.
DNA functionalized Multi layered Surface Crosslinked Micelles (mlSCMs) can compartmentalize two small molecule cargo in distinct layers. In response to the appropriate trigger, mlSCMs can release cargo for chemical and biochemical applications.
Nucleic acid nanocapsules (NANs) are enzyme-responsive DNA-functionalized micelles built for the controlled release of DNA-surfactant conjugates (DSCs) that present sequences with demonstrated therapeutic potential. Here, we investigate the mechanisms by which DSCs gain access to intracellular space in vitro and determine the effects of serum on the overall uptake and internalization mechanism of NANs. Using pharmacological inhibitors to selectively block certain pathways, we show, through confocal visualization of cellular distribution and flow cytometry quantification of total cellular association, that scavenger receptor-mediated, caveolae-dependent endocytosis is the major cellular uptake pathway of NANs in the presence and absence of serum. Furthermore, as NANs can be triggered to release DSCs by external stimuli such as enzymes, we sought to examine the uptake profile of particles degraded by enzymes prior to cell-based assays. We found that while scavenger receptor-mediated, caveolae-dependent endocytosis is still at play, energy-independent pathways as well as clathrin-mediated endocytosis are also involved. Overall, this study has helped to elucidate early steps in the cytosolic delivery and therapeutic activity of DSCs packaged into a micellular NAN platform while shedding light on the way in which DNA functionalized nanomaterials in general can be trafficked into cells both as nanostructures and as molecular entities. Importantly, our study also shows that the NAN design in particular is able to stabilize nucleic acids when delivered in the presence of serum, a critical step for effective therapeutic nucleic acid delivery.
Intracellular zinc ions are essential for various biological cell processes and are often dysregulated in many diseases de‐pending on their location, protein binding affinity, and concentration in the cell. Due to their prevalence in diseases, it is important to not only effectively sense but chelate the often excess amount of zinc in a cell to alleviate further disease progression. N, N, N′, N′‐tetrakis (2‐pyridinylmethyl)‐1,2‐ethanediamine (TPEN) is a selective zinc chelator but its water‐insoluble nature and general cytotoxicity limit its therapeutic potential. To address these challenges, TPEN loaded nucleic acid nanocapsules (TL‐NANs) were synthesized, and its dual ability to sense and suppress zinc levels intracellularly were evaluated. Additionally, TL‐NANs were incubated in lung cells and shown to down regulate Eotaxin, a protein up‐regulated during asthma, at significantly reduced concentrations of TPEN showcasing the therapeutic potential of this drug for asthma.
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