Background

DNA origami is a relatively recent technique first described in 2003 as a method of folding DNA into complex structures [1]. Since then there has been an effort to find practical applications for DNA origami, many of which involve targeted in vivo delivery of drug payloads [2], antigens [3], and siRNA [4]. We believe however, that the strongest potential is for delivery of the DNA itself by incorporating the gene vector into the origami for cellular uptake.

The viral method is the currently the most efficient at transfecting mammalian cells due to the intrinsic ability of the viral vector. However because of the immunogenic properties of the viral vehicle and its high production costs, artificial non-viral methods are being investigated. Inorganic nanoparticles are especially tantalizing due to their synthetic production, durable storage, and resistance to premature degradation or digestion. The most common types of nanoparticles include cationic polymers, liposomes, gold clusters, and silicate particles. Among them, two successful commercial agents are Polyfect® (dendritic polymer) and Lipofectamine® (liposome). To have transfection efficiencies comparable to these two products would be considered our standard of success.

One promising material that has yet to be fully realized is that of the calcium phosphate nanoparticle (CPNP). First described 35 years ago[5], Calcium phosphate is non-toxic, easily biodegradable, and is simply precipitated in aqueous solutions. The greatest technical challenge in their production is ensuring stable uniform sizes. Many labs have gone on to show that CPNP improves the uptake of their active agents into the cell, whether they be flourophores [6], antigens and immunoactive oligonucleotide [7], or therapeutic genes [8]. This improved uptake by CPNPs can be due to a number of reasons, including the size of the nanoparticle, the conglomeration the agent, improved binding of the CPNP to the membrane with resulting endocytosis, and the enhanced endosomal escape of the agent intracellularly. Whatever the mechanism may be, CPNPs are an especially non-toxic easily synthesized delivery vehicle for gene vectors.

Initial attempts at gene therapy had the DNA coated on the outside of the nanoparticle [3, 8], more recently

We first set out to develop a method of transfecting cells by a novel approach of encapsulating DNA origami with calcium phosphate to form biocompatible nanoparticles. This was a combinatorial process,

Another potential advantage is the effect the DNA origami may have on the shape of the nanoparticle. DNA origami is most easily folded into cylindrical rods, and so the precipitation of the calcium phosphate onto the origami may induce a cylindrical shape to the nanoparticle as well. It was shown in 2008[9] that cylindrical nanoparticles with a high aspect ratio showed a higher rate of internalization than their more symmetrical counterparts.

Our Focus

To do this and that. See our Methods for more.

Our Goals

1. Goal
2. Goal
3. Goal
4. Gooooaal!

1. Rothemund PW. Folding DNA to create nanoscale shapes and patterns. Nature. 2006 Mar 16;440(7082):297-302. DOI:10.1038/nature04586 | PubMed ID:16541064 | HubMed [Rothemund]
2. Douglas SM, Bachelet I, and Church GM. A logic-gated nanorobot for targeted transport of molecular payloads. Science. 2012 Feb 17;335(6070):831-4. DOI:10.1126/science.1214081 | PubMed ID:22344439 | HubMed [Douglas]
3. Schüller VJ, Heidegger S, Sandholzer N, Nickels PC, Suhartha NA, Endres S, Bourquin C, and Liedl T. Cellular immunostimulation by CpG-sequence-coated DNA origami structures. ACS Nano. 2011 Dec 27;5(12):9696-702. DOI:10.1021/nn203161y | PubMed ID:22092186 | HubMed [Liu]
3. Liu T, Tang A, Zhang G, Chen Y, Zhang J, Peng S, and Cai Z. Calcium phosphate nanoparticles as a novel nonviral vector for efficient transfection of DNA in cancer gene therapy. Cancer Biother Radiopharm. 2005 Apr;20(2):141-9. DOI:10.1089/cbr.2005.20.141 | PubMed ID:15869447 | HubMed [Liu]
4. Lee H, Lytton-Jean AK, Chen Y, Love KT, Park AI, Karagiannis ED, Sehgal A, Querbes W, Zurenko CS, Jayaraman M, Peng CG, Charisse K, Borodovsky A, Manoharan M, Donahoe JS, Truelove J, Nahrendorf M, Langer R, and Anderson DG. Molecularly self-assembled nucleic acid nanoparticles for targeted in vivo siRNA delivery. Nat Nanotechnol. 2012 Jun 3;7(6):389-93. DOI:10.1038/nnano.2012.73 | PubMed ID:22659608 | HubMed [Lee]
5. Graham FL and van der Eb AJ. A new technique for the assay of infectivity of human adenovirus 5 DNA. Virology. 1973 Apr;52(2):456-67. DOI:10.1016/0042-6822(73)90341-3 | PubMed ID:4705382 | HubMed [Graham]
6. Altinoğlu EI, Russin TJ, Kaiser JM, Barth BM, Eklund PC, Kester M, and Adair JH. Near-infrared emitting fluorophore-doped calcium phosphate nanoparticles for in vivo imaging of human breast cancer. ACS Nano. 2008 Oct 28;2(10):2075-84. DOI:10.1021/nn800448r | PubMed ID:19206454 | HubMed [Altinoglu]
7. Sokolova V, Knuschke T, Kovtun A, Buer J, Epple M, and Westendorf AM. The use of calcium phosphate nanoparticles encapsulating Toll-like receptor ligands and the antigen hemagglutinin to induce dendritic cell maturation and T cell activation. Biomaterials. 2010 Jul;31(21):5627-33. DOI:10.1016/j.biomaterials.2010.03.067 | PubMed ID:20417963 | HubMed [Skolova]
8. Zhang G, Liu T, Chen YH, Chen Y, Xu M, Peng J, Yu S, Yuan J, and Zhang X. Tissue specific cytotoxicity of colon cancer cells mediated by nanoparticle-delivered suicide gene in vitro and in vivo. Clin Cancer Res. 2009 Jan 1;15(1):201-7. DOI:10.1158/1078-0432.CCR-08-1094 | PubMed ID:19118047 | HubMed [Zhang]
9. Gratton SE, Ropp PA, Pohlhaus PD, Luft JC, Madden VJ, Napier ME, and DeSimone JM. The effect of particle design on cellular internalization pathways. Proc Natl Acad Sci U S A. 2008 Aug 19;105(33):11613-8. DOI:10.1073/pnas.0801763105 | PubMed ID:18697944 | HubMed [Gratton]

All Medline abstracts: PubMed | HubMed

• Paul M Gruenbacher 12:42, 14 April 2013 (EDT):