Dynamic monitoring of oncolytic adenovirus in vivo by genetic capsid labeling.

BACKGROUND: Conditionally replicative adenoviruses represent a promising strategy to address the limited efficacy and safety issues associated with conventional cancer treatment. Despite rapid translation into human clinical trials and demonstrated safety, the fundamental properties of oncolytic adenovirus replication and spread and host-vector interactions in vivo have not been completely evaluated. METHODS: We developed a noninvasive dynamic monitoring system to detect adenovirus replication. We constructed capsid-labeled E1/E3-deleted and wild-type adenoviruses (Ad-wt) by fusing the minor capsid protein IX with red fluorescent proteins mRFP1 and tdimer2(12), resulting in Ad-IX-mRFP1, Ad-IX-tdimer2(12), and Ad-wt-IX-mRFP1. Virus DNA replication, encapsidation, cytopathic effect, thermostability, and binding to primary receptor (coxsackie adenovirus receptor) were analyzed using real-time quantitative polymerase chain reaction, cell viability (MTS) assay, and fluorescence microscopy. Athymic mice (n = 4) carrying xenograft tumors that were derived from A549 lung adenocarcinoma cells were intratumorally inoculated with Ad-wt-IX-mRFP1, and adenovirus replication was dynamically monitored with a fluorescence noninvasive imaging system. Correlations between fluorescence signal intensity and viral DNA synthesis and replication were calculated using Pearson's correlation coefficient (r). RESULTS: The red fluorescence label had little effect on viral DNA replication, encapsidation, cytopathic effect, thermostability, and coxsackie adenovirus receptor binding. The fluorescent signal correlated with viral DNA synthesis and infectious progeny production both in vitro and in vivo (in A549 cells, r = .99 and r = .65; in tumors, r = .93 and r = .92, respectively). The replication efficiency of Ad-wt-IX-mRFP1 in vivo was variable, and replication and viral spreading and persistence were limited, consistent with clinical observations. CONCLUSIONS: Genetic capsid labeling provides a promising approach for the dynamic assessment of oncolytic adenovirus function in vivo.

Noninvasive visualization of adenovirus replication with a fluorescent reporter in the E3 region.

To overcome the inefficacy and undesirable side effects of current cancer treatment strategies, conditionally replicative adenoviruses have been developed to exploit the unique mechanism of oncolysis afforded by tumor-specific viral replication. Despite rapid translation into clinical trials and the established safety of oncolytic adenoviruses, the in vivo function of these agents is not well understood due to lack of a noninvasive detection system for adenovirus replication. To address this issue, we propose the expression of a reporter from the adenovirus E3 region as a means to monitor replication. Adenovirus replication reporter vectors were constructed with the enhanced green fluorescent protein (EGFP) gene placed in the deleted E3 region under the control of the adenoviral major late promoter while retaining expression of the adenovirus death protein to conserve the native oncolytic capability of the virus. Strong EGFP fluorescence was detected from these vectors in a replication-dependent manner, which correlated with viral DNA replication. Fluorescence imaging in vivo confirmed the ability to noninvasively detect fluorescent signal during replication, which generally corresponded with the underlying level of viral DNA replication. EGFP representation of viral replication was further confirmed by Western blot comparison with the viral DNA content in the tumors. Imaging reporter expression controlled by the adenoviral major late promoter provides a viable approach to noninvasively monitor adenovirus replication in preclinical studies and has the potential for human application with clinically relevant imaging reporters.

Promoter-controlled infectivity-enhanced conditionally replicative adenoviral vectors for the treatment of gastric cancer.

BACKGROUND: Gastric cancer is the fourth most common malignancy worldwide. Adenoviral vectors (Ads) have been applied for gene therapy of various cancers because of their high transduction efficiency. However, the infectivity of gastrointestinal cancer cells is poor due to the limited expression of the Coxsackie-adenovirus receptor (CAR). In addition, few tumor-specific promoters (TSPs) have been characterized for this type of cancer. To overcome these problems, we proposed TSP-driven conditionally replicating adenoviruses (CRAds) with fiber modification for virotherapy of gastric cancer. METHODS: We assessed the expression profile of eight TSPs in gastric cancer cell lines and evaluated promising candidates in the context of CRAd cytocidal effect. Next, infectivity enhancement by fiber modifications was analyzed in the gastric cancer cell lines. Finally, we combined the TSP-driven CRAds of choice with the fiber modifications to augment the killing effect. RESULTS: Out of the eight TSPs, the midkine (MK) and cyclooxygenase-2 (Cox-2M and Cox-2L) promoters showed high transcriptional activity in gastric cancer cells. When these promoters were used in a CRAd context, Cox-2 CRAds elicited the strongest cytocidal effect. The greatest infectivity enhancement was observed with adenoviral vectors displaying 5/3 chimeric fibers. Likewise, Cox-2 CRAds with 5/3 chimeric fibers showed the strongest cytocidal effect in gastric cancer cell lines. Therefore, Cox-2 CRAds with 5/3 chimeric fiber modification showed good selectivity and infectivity in gastric cancer cells to yield enhanced oncolysis. CONCLUSIONS: Cox-2 CRAds with 5/3 chimeric fiber modification are promising for virotherapy of gastric cancer.

Fluorescently labeled adenovirus with pIX-EGFP for vector detection.

Adenoviruses are extensively studied in terms of their use as gene therapy vectors and pathogenesis. These vectors have been targeted on both transcriptional and transductional levels to achieve cell-specific gene delivery. Current detection strategies, including reporter gene expression, viral component detection, and vector labeling with fluorophores, have been applied to analyze adenoviral vectors; however, these methods are inadequate for assessing transductional targeting. As an alternative to conventional vector detection techniques, we developed a specific genetic labeling system whereby an adenoviral vector incorporates a fusion between capsid protein IX and EGFP. DNA packaging and thermostability were marginally hampered by the modification while DNA replication, cytopathic effect, and CAR-dependent binding were not affected. The fluorescent label was associated with the virus capsid and conferred a fluorescent property useful in detecting adenoviral particles in flow cytometry, tracking, and tissue sections. We believe our genetic adenovirus labeling system has important implications for vector development, detecting adenovirus vectors in targeting schemes, and studying adenovirus biology. In addition, this technique has potential utility for dynamic monitoring of adenovirus replication and spread.