Selection and Characterization of a DNA Aptamer Specifically Targeting Human HECT Ubiquitin Ligase WWP1.

Nucleic acid aptamers hold promise as therapeutic tools for specific, tailored inhibition of protein targets with several advantages when compared to small molecules or antibodies. Nuclear WW domain containing E3 ubiquitin ligase 1 (WWP1) ubiquitin ligase poly-ubiquitinates Runt-related transcription factor 2 (Runx2), a key transcription factor associated with osteoblast differentiation. Since WWP1 and an adapter known as Schnurri-3 are negative regulators of osteoblast function, the disruption of this complex has the potential to increase bone deposition for osteoporosis therapy. Here, we develop new DNA aptamers that bind and inhibit WWP1 then investigate efficacy in an osteoblastic cell culture. DNA aptamers were selected against three different truncations of the HECT domain of WWP1. Aptamers which bind specifically to a C-lobe HECT domain truncation were observed to enrich during the selection procedure. One particular DNA aptamer termed C3A was further evaluated for its ability to bind WWP1 and inhibit its ubiquitination activity. C3A showed a low µM binding affinity to WWP1 and was observed to be a non-competitive inhibitor of WWP1 HECT ubiquitin ligase activity. When SaOS-2 osteoblastic cells were treated with C3A, partial localization to the nucleus was observed. The C3A aptamer was also demonstrated to specifically promote extracellular mineralization in cell culture experiments. The C3A aptamer has potential for further development as a novel osteoporosis therapeutic strategy. Our results demonstrate that aptamer-mediated inhibition of protein ubiquitination can be a novel therapeutic strategy.

The gene transfection efficiency of a folate-PEI600-cyclodextrin nanopolymer.

The success of gene therapy relies on a safe and effective gene delivery system. In this communication, we describe the use of folate grafted PEI(600)-CyD (H(1)) as an effective polyplex-forming plasmid delivery agent with low toxicity. The structures of the polymer and polyplex were characterized, and the in vitro transfection efficiency, cytotoxicity, and in vivo transfection of H(1) were examined. We found that folate molecules were successfully grafted to PEI(600)-CyD. At N/P ratios between 5 and 30, the resulting H(1)/DNA polyplexes had diameters less than 120 nm and zeta potentials less than 10 mV. In various tumor cell lines examined (U138, U87, B16, and Lovo), the in vitro transfection efficiency of H(1) was more than 50%, which could be improved by the presence of fetal bovine serum or albumin. The cytotoxicity of H(1) was significantly less than high molecular weight PEI-25 kDa. Importantly, in vivo optical imaging showed that the efficiency of H(1)-mediated transfection (50 microg luciferase plasmid (pLuc), N/P ratio=20/1) was comparable to that of adenovirus-mediated luciferase transduction (1 x 10(9) pfu) in melanoma-bearing mice, and it did not induce any toxicity in the tumor tissue. These results clearly show that H(1) is a safe and effective polyplex-forming agent for both in vitro and in vivo transfection of plasmid DNA and its application warrants further investigation.