Our goal is to develop robust siRNA and micro-RNA methods to regulate genes for basic research, permitting both temporal and spatial control of transfection with high efficiency in both cell culture and C. elegans by using the unique chemical and physical properties of hollow gold nanoshells (HGN). HGNs are 30 - 40 nm diameter, 3-5 nm thick, gold shells designed to strongly absorb physiologically friendly NIR light and convert this light energy into local heating. HGN can be easily conjugated to small molecules, targeting ligands, polymers, siRNA and DNA by simple thiol chemistry, or incorporated into or tethered to liposomes. Water, proteins, lipids, etc. do not absorb NIR light, so cells in culture are essentially transparent, which eliminates damage during exposure. Femtosecond NIR light pulses trigger release of thiol-conjugated siRNA or other molecules from the HGN by breaking thiol bonds without damaging the siRNA. Even more important to the development of efficient oligonucleotide and small molecule delivery, the well-known bottleneck of endosomal escape can be bypassed by converting the physiologically friendly NIR light energy absorbed by the HGN to heat, creating unstable microbubbles that mechanically rupture endosomes and release siRNA to the cytosol within seconds. This allows much lower concentrations of HGN-siRNA conjugates to be used, greatly increases transfection efficiency, and provides spatially and temporally controlled transfection that can be used to pattern cultured cells and address specific structures within C. elegans. HGN transfection is as efficient as Lipofectamine, but is non-toxic, and can be used in living organisms. In this proposal, we will use the HGN-siRNA platform to develop masking and unmasking techniques for activating or inactivating biological processes with remote control to devise simple and scalable methods of lithographic patterning of cultured cells in real time. We will investigate controlled release of small molecules from liposomes incorporating HGN using NIR light triggering to control release, thereby enabling basic cell biological studies, including human stem cell differentiation, cancer biology, and signal transduction pathways and routes to applications in chemotherapy and drug delivery. We will develop methods to multiplex the release from a single HGN using a combination of thiol and dithiol anchors that desorbs at different energies to release of multiple chemical species. New silver nanoshells and gold and silver nanorods will be synthesized to probe other regions of the NIR spectrum and provide simultaneous delivery and imaging opportunities. These new constructs could be addressed independently by using different wavelength NIR irradiation. This project takes full advantage of the unique HGN interactions with physiologically friendly NIR light to initiate and control biological processes with precise spatial control at millisecond rates in living cells and organisms.
Effective use of RNAi and small molecule therapies are limited by the well-known bottleneck of endosome release. We are developing a novel platform based on hollow gold nanoshells (30 nm diameter) that adsorb physiologically friendly, highly penetrating near infrared light (NIR). The light energy is efficiently converted to heat, leading to formation of vapor microbubbles that mechanically rupture endosomes and can release thiol-conjugated siRNA to induce gene silencing. This allows much lower concentrations of HGN-siRNA conjugates to be used and greatly increases the transfection efficiency. The method provides rapid, spatially and temporally controlled release of drugs or genetic materials from HGN conjugates or liposome carriers within living cells. HGN transfection is as efficient as Lipofectamine, but is non-toxic, can be used in living organisms, and holds the promise of transfecting single cells in mixed culture. The HGN- siRNA platform is capable of activating or inactivating biological processes with remote control so as to make possible simple and scalable methods of lithographic patterning of cultured cells in real time.
Morales, Demosthenes P; Wonderly, William R; Huang, Xiao et al. (2017) Affinity-Based Assembly of Peptides on Plasmonic Nanoparticles Delivered Intracellularly with Light Activated Control. Bioconjug Chem 28:1816-1820 |
Levy, Elizabeth S; Morales, Demosthenes P; Garcia, John V et al. (2015) Near-IR mediated intracellular uncaging of NO from cell targeted hollow gold nanoparticles. Chem Commun (Camb) 51:17692-5 |
Morales, Demosthenes P; Braun, Gary B; Pallaoro, Alessia et al. (2015) Targeted intracellular delivery of proteins with spatial and temporal control. Mol Pharm 12:600-9 |
Forbes, Natalie; Shin, Jeong Eun; Ogunyankin, Maria et al. (2015) Inside-outside self-assembly of light-activated fast-release liposomes. Phys Chem Chem Phys 17:15569-78 |
Huang, Xiao; Hu, Qirui; Braun, Gary B et al. (2015) Light-activated RNA interference in human embryonic stem cells. Biomaterials 63:70-9 |
Huang, Xiao; Pallaoro, Alessia; Braun, Gary B et al. (2014) Modular plasmonic nanocarriers for efficient and targeted delivery of cancer-therapeutic siRNA. Nano Lett 14:2046-51 |
Forbes, Natalie; Pallaoro, Alessia; Reich, Norbert O et al. (2014) Rapid, Reversible Release from Thermosensitive Liposomes Triggered by Near-Infra-Red Light. Part Part Syst Charact 31:1158-1167 |
Gottstein, Claudia; Wu, Guohui; Wong, Benjamin J et al. (2013) Precise quantification of nanoparticle internalization. ACS Nano 7:4933-45 |
Lukianova-Hleb, Ekaterina Y; Ren, Xiaoyang; Zasadzinski, Joseph A et al. (2012) Plasmonic nanobubbles enhance efficacy and selectivity of chemotherapy against drug-resistant cancer cells. Adv Mater 24:3831-7 |
Zasadzinski, Joseph A; Wong, Benjamin; Forbes, Natalie et al. (2011) Novel Methods of Enhanced Retention in and Rapid, Targeted Release from Liposomes. Curr Opin Colloid Interface Sci 16:203-214 |
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