Effect of physicochemical properties on intranasal nanoparticle transit into murine olfactory epithelium.

Small molecular weight drugs, peptides, and nanoparticles have previously been shown to localize in the central nervous system after intraneural administration. A basic understanding of direct nose-to-brain drug delivery, particularly for nanoparticles with different physicochemical characteristics, remains unclear. In this study, fluorescence microscopy and stereology were used to track intranasally administered chitosan-coated polystyrene (C-PS) or polysorbate-coated polystyrene (P80-PS) nanoparticles (100 nm or 200 nm in diameter) in olfactory and respiratory nasal epithelia and olfactory bulbs in mice. Chitosan coating caused particles to adhere to the extracellular mucus which could provide useful modality for paracellular drug transport. Nanoparticle transport was exclusively transcellular. None of the nanoparticle formulations showed preference for uptake into olfactory axons over other nasal epithelial cells. Both 100 nm PS and 100 nm P80-PS were observed in olfactory epithelial cells but were absent from the olfactory bulbs; therefore, it is speculated that an optimal nanoparticle diameter for axonal transport is <100 nm in mice.

Naked siLNA-mediated gene silencing of lung bronchoepithelium EGFP expression after intravenous administration.

The use of systemic siRNA therapeutics for RNA interference-mediated silencing of disease genes is limited by serum instability and inadequate biodistribution. We have previously reported on the EGFP gene silencing effect of chitosan/siRNA nanoparticles in the bronchoepithelium of mice lungs following intranasal delivery and improved serum stability and reduced off-targeting effects in vitro by incorporation of locked nucleic acid (LNA). In this study, we examine the pulmonary gene silencing effect of siLNAs targeting enhanced-green-fluorescent-protein (EGFP) in lung bronchoepithelium upon intravenous delivery of naked siLNAs and upon intranasal delivery of either naked siLNA or chitosan/siLNA nanoparticles. We show that naked siLNA administered intravenously efficiently reduces the EGFP protein expression. A similar effect is obtained with intranasal delivery of chitosan nanoparticles containing siLNA whereas intranasally instilled naked siLNA did not cause a knockdown.

RNA interference in vitro and in vivo using a novel chitosan/siRNA nanoparticle system.

This work introduces a novel chitosan-based siRNA nanoparticle delivery system for RNA interference in vitro and in vivo. The formation of interpolyelectrolyte complexes between siRNA duplexes (21-mers) and chitosan polymer into nanoparticles, ranging from 40 to 600 nm, was shown using atomic force microscopy and photon correlation spectroscopy. Rapid uptake (1 h) of Cy5-labeled nanoparticles into NIH 3T3 cells, followed by accumulation over a 24 h period, was visualized using fluorescence microscopy. Nanoparticle-mediated knockdown of endogenous enhanced green fluorescent protein (EGFP) was demonstrated in both H1299 human lung carcinoma cells and murine peritoneal macrophages (77.9% and 89.3% reduction in EGFP fluorescence, respectively). In addition, Western analysis showed approximately 90% reduced expression of BCR/ABL-1 leukemia fusion protein while BCR expression was unaffected in K562 (Ph(+)) cells after transfection using nanoparticles containing siRNA specific to the BCR/ABL-1 junction sequence. Effective in vivo RNA interference was achieved in bronchiole epithelial cells of transgenic EGFP mice after nasal administration of chitosan/siRNA formulations (37% and 43% reduction compared to mismatch and untreated control, respectively). These findings highlight the potential application of this novel chitosan-based system in RNA-mediated therapy of systemic and mucosal disease.

A tumor-suppressor function for NFATc3 in T-cell lymphomagenesis by murine leukemia virus.

Nuclear factor of activated T cell (NFAT) transcription factors play a central role in differentiation, activation, and elimination of lymphocytes. We here report on the finding of provirus integration into the Nfatc3 locus in T-cell lymphomas induced by the murine lymphomagenic retrovirus SL3-3 and show that NFATc3 expression is repressed in these lymphomas. The provirus insertions are positioned close to the Nfatc3 promoter or a putative polyadenylated RNA (polyA) region. Furthermore, we demonstrate that NFATc3-deficient mice infected with SL3-3 develop T-cell lymphomas faster and with higher frequencies than wild-type mice or NFATc2-deficient mice. These results identify NFATc3 as a tumor suppressor for the development of murine T-cell lymphomas induced by the retrovirus SL3-3.