Neil S. Forbes

We demonstrate here the effective delivery of a dye payload into cells using 2-nm core gold nanoparticles, with release occurring via place exchange of glutathione onto the particle surface. In vitro experiments demonstrate effective release of drug analogues upon addition of glutathione. Cell culture experiments show rapid uptake of nanoparticle and effective release of payload. The role of glutathione in the release process was demonstrated through improved payload release upon transient increase in glutathione levels achieved via introduction of glutathione ethyl ester into the cell.

Gold colloids functionalized with amino acids provide a scaffold for effective DNA binding with subsequent condensation. Particles with lysine and lysine dendron functionality formed particularly compact complexes and provided highly efficient gene delivery without any observed cytotoxicity. Nanoparticles functionalized with first generation lysine dendrons (NP-LysG1) were approximately 28-fold superior to polylysine in reporter gene expression. These amino acid-based nanoparticles were responsive to intracellular glutathione levels, providing a tool for controlled release and concomitant expression of DNA.

PURPOSE: Low extracellular pH is a hallmark of solid tumors. It has long been thought that this acidity is mainly attributable to the production of lactic acid. In this study, we tested the hypothesis that lactate is not the only source of acidification in solid tumors and explored the potential mechanisms underlying these often-observed high rates of acid production. EXPERIMENTAL DESIGN: We compared the metabolic profiles of glycolysis-impaired (phosphoglucose isomerase-deficient) and parental cells in both in vitro and two in vivo models (dorsal skinfold chamber and Gullino chamber). RESULTS: We demonstrated that CO(2), in addition to lactic acid, was a significant source of acidity in tumors. We also found evidence supporting the hypothesis that tumor cells rely on glutaminolysis for energy production and that the pentose phosphate pathway is highly active within tumor cells. Our results also suggest that the tricarboxylic acid cycle is saturable and that different metabolic pathways are activated to provide for energy production and biosynthesis. CONCLUSIONS: These results are consistent with the paradigm that tumor metabolism is determined mainly by substrate availability and not by the metabolic demand of tumor cells per se. In particular, it appears that the local glucose and oxygen availabilities each independently affect tumor acidity. These findings have significant implications for cancer treatment.