A molecular imaging system based on both transcriptional and genomic amplification to detect prostate cancer cells in vivo.

An imaging modality that can accurately discern prostate cancer (PCa) foci would be useful to detect PCa early or guide treatment. We have engineered numerous adenoviral vectors (Ads) to carry out reporter gene-based imaging using specific promoters to express a potent transcriptional activator, which in turn activates the reporter gene in PCa. This two-step transcriptional amplification (TSTA) method can boost promoters' activity, while maintaining cell specificity. Here, we examined a dual TSTA (DTSTA) approach, which utilizes TSTA not only to express the imaging reporter, but also to direct viral genome replication of a conditionally replicating Ad (CRAd) to further augment the expression levels of the reporter gene by genomic amplification supported in trans by coadministered CRAd. In vitro studies showed up to 50-fold increase of the reporter genome by DTSTA. Compared with TSTA reporter alone, DTSTA application exhibited a 25-fold increase in imaging signal in PCa xenografts. DTSTA approach is also beneficial for a combination of two TSTA Ads with distinct promoters, although amplification is observed only when TSTA-CRAd can replicate. Consequently, the DTSTA approach is a hybrid method of transcriptional and genomic augmentation that can provide higher level reporter gene expression potentially with a lower dose of viral administration.

Differential biodistribution of adenoviral vector in vivo as monitored by bioluminescence imaging and quantitative polymerase chain reaction.

A better understanding of the in vivo biodistribution of adenoviral vectors would enable the researcher to anticipate potential side effects due to off-targeted site of transduction, and aid in the strategic design of gene therapy. We combined real-time polymerase chain reaction with in vivo optical imaging to examine viral transduction in liver, lung, spleen, kidney, prostate, and lymph nodes. A replication-deficient serotype 5 adenoviral vector expressing the firefly luciferase gene under the control of a constitutive cytomegalovirus promoter was administered in vivo via different routes. Intravenous and intraperitoneal injections resulted in greatest gene expression and viral DNA in the liver, whereas intraperitoneal injections led to a greater extent of gene delivery to the prostate. Although prostate-directed injection resulted in dominant gene expression in the targeted site, leakage of the vector to other organs was also observed. Vector injection into the lymphatic-rich paw tissue or the subcutaneous tissue of shoulder or chest followed the expected lymphatic drainage pattern, resulting in the accumulation of viral vector in ipsilateral brachial and axillary lymph nodes. Collectively, this study demonstrates that each tissue retains various amounts of adenoviral vector, depending on the route of administration. This knowledge is useful in the strategic design and implementation of adenovirus-mediated gene therapies.