| Abstract: |
Purpose: Radionuclide-based reporter gene imaging has the sensitivity to monitor gene- and cell-based therapies in human subjects. Potential immunogenicity of current viral transgenes warrants development of human-based reporter systems. We compared human nucleoside kinase reporters to a panel of nucleoside analogs of FEAU, FMAU, and FIAU, including the first in vivo assessment of l-[18F]FEAU. Procedures: Human isogenic U87 cell lines were transduced to express different human reporter genes including dCK-R104M/D133A (dCKDM), dCK-R104Q/D133N (dCKep16A), dCK-A100V/R104M/D133A (dCK3M), and TK2-N93D/L109F (TK2DM), and wild-type dCK (dCK) and herpes simplex virus type-1 (HSVTK) reporter gene as references. In vitro cell uptake assays were performed with [18F]FEAU, l-[18F]FEAU, [14C]FMAU, l-[18F]FMAU, and [124I]FIAU. Micro-positron emission tomography/X-ray computed tomography imaging of xenograft-bearing nu/nu mice was conducted with [18F]FEAU, l-[18F]FEAU, l-[18F]FMAU, and [124I]FIAU on consecutive days. A cell viability assay was also performed to assess sensitivities to gemcitabine and bromovinyldeoxyuridine (BVdU). Results: In vitro, dCKep16A and dCKDM with [18F]FEAU exhibited the highest sensitivity and selectivity of the human reporters, second only to HSVTK/[18F]FEAU. l-[18F]FEAU biodistribution in mice was on par with [18F]FEAU and l-[18F]FMAU. l-[18F]FMAU uptake in isogenic xenografts was highest for all human reporter genes. However, [18F]FEAU was the most selective of the short half-life reporter probes due to its minimal recognition by human dCK and relative sensitivity, whereas [124I]FIAU permitted imaging at a later time point, improving signal-to-background ratio. Of the human reporter genes, dCKep16A consistently outperformed the other tested reporters. Reporter genes of interest increased potency to the nucleoside analog prodrugs gemcitabine and BVdU. Conclusions: We demonstrate that human nucleoside kinase reporter systems vary significantly in their sensitivity and selectivity for in vivo imaging. The sufficiently high signal-to-background ratios and enhanced suicide gene potential support clinical translation. © 2016, World Molecular Imaging Society. |
