Development of DNA Nanostructures for High-Affinity Binding to Human Serum Albumin.

The development of nucleic acid therapeutics has been hampered by issues associated with their stability and in vivo delivery. To address these challenges, we describe a new strategy to engineer DNA structures with strong binding affinity to human serum albumin (HSA). HSA is the most abundant protein in the blood and has a long circulation half-life (19 days). It has been shown to hinder phagocytosis, is retained in tumors, and aids in cellular penetration. Indeed, HSA has already been successfully used for the delivery of small-molecule drugs and nanoparticles. We show that conjugating dendritic alkyl chains to DNA creates amphiphiles that exhibit high-affinity (Kd in low nanomolar range) binding to HSA. Notably, complexation with HSA did not hinder the activity of silencing oligonucleotides inside cells, and the degradation of DNA strands in serum was significantly slowed. We also show that, in a site-specific manner, altering the number and orientation of the amphiphilic ligand on a self-assembled DNA nanocube can modulate the affinity of the DNA cage to HSA. Moreover, the serum half-life of the amphiphile bound to the cage and the protein was shown to reach up to 22 hours, whereas unconjugated single-stranded DNA was degraded within minutes. Therefore, adding protein-specific binding domains to DNA nanostructures can be used to rationally control the interface between synthetic nanostructures and biological systems. A major challenge with nanoparticles delivery is the quick formation of a protein corona (i.e., protein adsorbed on the nanoparticle surface) upon injection to biological media. We foresee such DNA cage-protein complexes as new tools to study the role of this protein adsorption layer with important implications in the efficient delivery of RNAi therapeutics in vitro and in vivo.

[1]  Paul W. Wiseman,et al.  Sequence-responsive unzipping DNA cubes with tunable cellular uptake profiles , 2014 .

[2]  H. Sleiman,et al.  Site-specific positioning of dendritic alkyl chains on DNA cages enables their geometry-dependent self-assembly. , 2013, Nature chemistry.

[3]  Matthew J. A. Wood,et al.  DNA cage delivery to mammalian cells. , 2011, ACS nano.

[4]  Felix Kratz,et al.  Albumin as a drug carrier: design of prodrugs, drug conjugates and nanoparticles. , 2008, Journal of controlled release : official journal of the Controlled Release Society.

[5]  Faisal A. Aldaye,et al.  A facile, modular and high yield method to assemble three-dimensional DNA structures. , 2011, Chemical communications.

[6]  Leslie R Evans,et al.  Albumin as a versatile platform for drug half-life extension. , 2013, Biochimica et biophysica acta.

[7]  J. Marmur,et al.  Denaturation of deoxyribonucleic acid by formamide. , 1961, Biochimica et biophysica acta.

[8]  Chad A. Mirkin,et al.  Nanotechnology-Based Precision Tools for the Detection and Treatment of Cancer. , 2015, Anticancer research.

[9]  F. Kratz,et al.  Serum proteins as drug carriers of anticancer agents: a review. , 1998, Drug delivery.

[10]  H. Sleiman,et al.  DNA nanostructure serum stability: greater than the sum of its parts. , 2013, Chemical communications.

[11]  W. Mark Saltzman,et al.  Therapeutic siRNA: Principles, Challenges, and Strategies , 2012, The Yale journal of biology and medicine.

[12]  J. Kjems,et al.  Self-assembly of a nanoscale DNA box with a controllable lid , 2009, Nature.

[13]  V. Trezza,et al.  Human serum albumin: from bench to bedside. , 2012, Molecular aspects of medicine.

[14]  H. Maeda,et al.  Exploiting the enhanced permeability and retention effect for tumor targeting. , 2006, Drug discovery today.

[15]  Hassan S. Bazzi,et al.  “DNA–Teflon” sequence-controlled polymers , 2016 .

[16]  L. Hellman,et al.  Electrophoretic mobility shift assay (EMSA) for detecting protein–nucleic acid interactions , 2007, Nature Protocols.

[17]  N. Seeman,et al.  Synthesis from DNA of a molecule with the connectivity of a cube , 1991, Nature.

[18]  G. Deleavey,et al.  Designing chemically modified oligonucleotides for targeted gene silencing. , 2012, Chemistry & biology.

[19]  Andrew J Turberfield,et al.  The single-step synthesis of a DNA tetrahedron. , 2004, Chemical communications.

[20]  Marco P Monopoli,et al.  Biomolecular coronas provide the biological identity of nanosized materials. , 2012, Nature nanotechnology.

[21]  E. Lesnik,et al.  Improving Antisense Oligonucleotide Binding to Human Serum Albumin: Dramatic Effect of Ibuprofen Conjugation , 2002, Chembiochem : a European journal of chemical biology.

[22]  N. Seeman Nanomaterials based on DNA. , 2010, Annual review of biochemistry.

[23]  P. Brick,et al.  Crystal structure of human serum albumin complexed with fatty acid reveals an asymmetric distribution of binding sites , 1998, Nature Structural Biology.

[24]  S. Lippard,et al.  Pt(IV) Prodrugs Designed to Bind Non-Covalently to Human Serum Albumin for Drug Delivery , 2014, Journal of the American Chemical Society.

[25]  A. Malik,et al.  Gp60 Activation Mediates Albumin Transcytosis in Endothelial Cells by Tyrosine Kinase-dependent Pathway* , 1997, The Journal of Biological Chemistry.

[26]  Daniel Anderson,et al.  Delivery materials for siRNA therapeutics. , 2013, Nature materials.

[27]  P. White,et al.  Enhanced extravasation, stability and in vivo cardiac gene silencing via in situ siRNA-albumin conjugation. , 2012, Molecular pharmaceutics.

[28]  Alaaldin M. Alkilany,et al.  Protein corona: Opportunities and challenges. , 2016, The international journal of biochemistry & cell biology.

[29]  Enzo Terreno,et al.  The extraordinary ligand binding properties of human serum albumin , 2005, IUBMB life.

[30]  Ick Chan Kwon,et al.  Drug delivery by a self-assembled DNA tetrahedron for overcoming drug resistance in breast cancer cells. , 2013, Chemical communications.

[31]  Felix Kratz,et al.  Impact of albumin on drug delivery--new applications on the horizon. , 2012, Journal of controlled release : official journal of the Controlled Release Society.

[32]  D. Richardson,et al.  Unraveling the mysteries of serum albumin—more than just a serum protein , 2014, Front. Physiol..

[33]  Michael Hawkins,et al.  Phase III trial of nanoparticle albumin-bound paclitaxel compared with polyethylated castor oil-based paclitaxel in women with breast cancer. , 2005, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[34]  Simon G. Patching,et al.  Surface plasmon resonance spectroscopy for characterisation of membrane protein-ligand interactions and its potential for drug discovery. , 2014, Biochimica et biophysica acta.

[35]  G. J. Vusse Albumin as Fatty Acid Transporter , 2008 .

[36]  Katharina Landfester,et al.  Controlling the Stealth Effect of Nanocarriers through Understanding the Protein Corona. , 2016, Angewandte Chemie.

[37]  Richard A. Muscat,et al.  DNA nanotechnology from the test tube to the cell. , 2015, Nature nanotechnology.

[38]  John C C Hsu,et al.  Optimized DNA "Nanosuitcases" for Encapsulation and Conditional Release of siRNA. , 2016, Journal of the American Chemical Society.

[39]  H. Sleiman,et al.  Development and characterization of gene silencing DNA cages. , 2014, Biomacromolecules.

[40]  A. Pêgo,et al.  Therapeutic antisense oligonucleotides against cancer: hurdling to the clinic , 2014, Front. Chem..

[41]  Yamuna Krishnan,et al.  Designing DNA nanodevices for compatibility with the immune system of higher organisms. , 2015, Nature nanotechnology.

[42]  Warren C W Chan,et al.  Understanding and controlling the interaction of nanomaterials with proteins in a physiological environment. , 2012, Chemical Society reviews.

[43]  H. Kamimori,et al.  Surface Plasmon Resonance Assay of Binding Properties of Antisense Oligonucleotides to Serum Albumins and Lipoproteins , 2015, Analytical sciences : the international journal of the Japan Society for Analytical Chemistry.

[44]  Hao Yan,et al.  Challenges and opportunities for structural DNA nanotechnology. , 2011, Nature nanotechnology.