Dynamic Monitoring of Oncolytic Adenovirus in Vivo by Genetic Capsid Labeling

Overview

Journal J Natl Cancer Inst

Publisher Oxford University Press

Specialty Oncology

Date 2006 Feb 2

PMID 16449680

Citations 24

Authors

Long P Le

Helen N Le

Igor P Dmitriev

Julia G Davydova

Tatyana Gavrikova

Seiji Yamamoto

David T Curiel

Masato Yamamoto

Affiliations

Soon will be listed here.

Abstract

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.

Citing Articles

Fluorescent protein tagging of adenoviral proteins pV and pIX reveals 'late virion accumulation compartment'.

Pfitzner S, Hofmann-Sieber H, Bosse J, Franken L, Grunewald K, Dobner T PLoS Pathog. 2020; 16(6):e1008588.

PMID: 32584886 PMC: 7343190. DOI: 10.1371/journal.ppat.1008588.

Oncolytic Viruses for Cancer Therapy: Barriers and Recent Advances.

Zheng M, Huang J, Tong A, Yang H Mol Ther Oncolytics. 2019; 15:234-247.

PMID: 31872046 PMC: 6911943. DOI: 10.1016/j.omto.2019.10.007.

Characterization of an Oncolytic Adenovirus Vector Constructed to Target the cMet Receptor.

Sakr H, Coleman D, Cardelli J, Mathis J Oncolytic Virother. 2016; 4:119-132.

PMID: 26866014 PMC: 4746000. DOI: 10.2147/OV.S87369.

Adenoviral protein V promotes a process of viral assembly through nucleophosmin 1.

Ugai H, Dobbins G, Wang M, Le L, Matthews D, Curiel D Virology. 2012; 432(2):283-95.

PMID: 22717133 PMC: 3423539. DOI: 10.1016/j.virol.2012.05.028.

Systemic delivery of a breast cancer-detecting adenovirus using targeted microbubbles.

Warram J, Sorace A, Saini R, Borovjagin A, Hoyt K, Zinn K Cancer Gene Ther. 2012; 19(8):545-52.

PMID: 22653385 PMC: 3417243. DOI: 10.1038/cgt.2012.29.