The use of so-called 'suicide' genes to activate prodrugs approach but reveal that hepatic expression of HSVtk, both has been effective in animal models for several solid tumor in tumor bearing and in tumor-free rats, provokes severe types and is now in phase I and II clinical trials. We have liver dysfunction and mortality upon GCV administration. exploited adenovirus vectors (Ad) for transfer and These data show, that in contrast to the common assumpexpression of the herpes simplex virus thymidine kinase tion, normally non-mitotic tissues too, can be affected by (HSVtk) gene to render rat colorectal liver metastases adenovirus-mediated HSVtk transfer and subsequent GCV sensitive to the anti-herpetic agent ganciclovir (GCV). The treatment. Given the hepatotropic nature of systemically efficacy and toxicity of this enzyme-prodrug combination administered adenovirus type 2-and 5-derived vectors, it were tested after in situ transduction of rat colorectal tumor will be essential to monitor liver functions of patients cells and after intraportal administration of the vector included in all gene therapy trials involving adenoviral vecAd.CMV.TK. Our results demonstrate the validity of the tors with the HSVtk gene.
Oncolytic adenoviruses exhibiting tumor-selective replication are promising anticancer agents. Insertion and expression of a transgene encoding tissue inhibitor of metalloproteinase-3 (TIMP-3), which has been reported to inhibit angiogenesis and tumor cell infiltration and induce apoptosis, may improve the antitumor activity of these agents. To assess the effects of TIMP-3 gene transfer to glioma cells, a replication-defective adenovirus encoding TIMP-3 (Ad.TIMP-3) was employed. Ad.TIMP-3 infection of a panel of glioma cell cultures decreased the proliferative capacity of these cells and induced morphologic changes characteristic for apoptosis. Next, a conditionally replicating adenovirus encoding TIMP-3 was constructed by inserting the TIMP-3 expression cassette into the E3 region of the adenoviral backbone containing a 24-bp deletion in E1A. This novel oncolytic adenovirus, Ad#24TIMP-3, showed enhanced oncolytic activity on a panel of primary cell cultures and two glioma cell lines compared with the control oncolytic virus Ad#24Luc. In vivo inhibition of matrix metalloproteinase (MMP) activity by Ad#24TIMP-3 was shown in s.c. glioma xenografts. The functional activity of TIMP-3 was imaged noninvasively using a near-IR fluorescent MMP-2-activated probe. Tumoral MMP-2 activity was significantly reduced by 58% in the Ad#24TIMP-3-treated tumors 24 hours after infection. A study into the therapeutic effects of combined oncolytic and antiproteolytic therapy was done in both a s.c. and an intracranial model for malignant glioma. Treatment of s.c. (U-87MG) or intracranial (U-87DEGFR) tumors with Ad#24TIMP-3 and Ad#24Luc both significantly inhibited tumor growth and prolonged survival compared with PBS-treated controls. However, expression of TIMP-3 in the context of Ad#24 did not significantly affect the antitumor efficacy of this oncolytic agent. (Cancer Res 2005; 65(20): 9398-405)
RNA interference (RNAi) is a posttranscriptional silencing mechanism triggered by double-stranded RNA that was recently shown to function in mammalian cells. Expression of cancer-associated genes was knocked down by expressing short hairpin RNAs (shRNAs) in cancer cells. By virtue of its excellent target specificity, RNAi may be used as a new therapeutic modality for cancer. The success of this approach will largely depend on efficient delivery of shRNAs to tumor cells. Tumor-selective replication competent viruses are especially suited to efficiently deliver anticancer genes to tumors. In addition, their intrinsic capacity to kill cancer cells makes these viruses promising anticancer agents per se. In this study, conditionally replicating adenoviruses were constructed encoding shRNAs targeted against firefly luciferase. These replicating viruses were shown to specifically silence the expression of the target gene in human cancer cells down to 30% relative to control virus. This finding offers the promise of using RNAi in the context of cancer gene therapy with oncolytic viruses.
Human monocyte-derived dendritic cells (DC) infected with recombinant adenoviruses (rAd) are promising candidate vaccines for inducing protective immunity against pathogens and tumors. However, since some viruses are known to negatively affect DC function, it is important to investigate the interactions between rAd and DC. We now show that infection by rAd enhances the immunostimulatory capacity of immature human monocyte-derived DC through the upregulation of the costimulatory molecules CD80, CD86, and CD40 and the major histocompatibility complex class I and II molecules. Although rAd infection fails to induce the secretion of interleukin-12 (IL-12) and only marginally induces the expression of the DC maturation marker CD83, it acts in synergy with CD40 triggering in rendering DC fully mature. rAd-infected DC triggered through CD40 produce more IL-12 and are more efficient in eliciting T-helper type 1 responses than DC activated by CD40 triggering only. rAd lacking one or more of the early regions, E1, E2A, E3, and E4, which play an important role in virus-host cell interactions are equally capable of DC activation. Efficient DC infection requires a high multiplicity of infection (>1,000), a fact which can be attributed to the absence of the coxsackievirus and adenovirus receptor on this cell type. Despite the poor ability of DC to be infected by rAd, which may be improved by targeting rAd to alternative DC surface molecules, DC infected with all currently tested rAd constitute potent immunostimulators. Our study provides new insights into the interactions between two highly promising vaccine components, rAd and DC, and indicates that their combination into one vaccine may be very advantageous for the stimulation of T-cell immunity.
No abstract
Targeting adenovirus vectors (AdV's) for selective transduction of specific cell types requires ablation of native adenovirus tropism and introduction of a unique target-binding moiety. To bring these requirements within reach, we developed a novel strategy to target AdV's genetically that relies on replacement of the entire adenovirus fiber protein with a fusion molecule comprising the virion-anchoring domain of fiber and the oligomerization domain of reovirus attachment protein sigma1. The chimeric molecule forms trimers, is transported to the nucleus, and assembles onto the adenovirus capsid. In contrast to previously reported genetically targeted vectors, the AdV presented herein propagates efficiently without a requirement for complementing fiber. Due to ablation of the native adenovirus tropism, the infectivity of this AdV was at least 35-fold reduced on 293 cells. Importantly, a His tag incorporated into the chimeric attachment protein conferred His-tag-dependent tropism to the AdV, which resulted in a 12- to 40-fold greater transduction efficiency on two different cell lines expressing a His-tag-binding receptor. In addition, the infection efficiency was strongly reduced by preincubation with a His-tag-specific Ab. Thus, this sigma1-based chimeric attachment molecule provides a promising new platform for the generation of truly targeted AdV's.
Despite improvements in treatment regimens for osteosarcoma (OS) patients, survival rate has not increased over the last two decades. New treatment modalities are therefore warranted. Preclinical results with conditionally replicative adenoviruses (CRAds) to treat OS are promising. One type of CRAd that was effective against OS cells is Ad5-D24RGD. In other types of cancer, CRAds have been shown to interact synergistically with chemotherapeutic agents. Chemotherapy for OS often includes doxorubicin and cisplatin. Therefore, we explored combination treatment of OS cell lines and primary OS cell cultures with Ad5-D24RGD and doxorubicin or cisplatin. On OS cell lines, combination treatment was additive to synergistic. Surprisingly, however, on seven of eight primary OS samples no such combination effects were observed. In contrast, in many cases chemotherapy even inhibited CRAdmediated cell killing. The inhibitory effect of doxorubicin on Ad5-D24RGD in primary OS cells appeared to correlate with slow cell growth rate; reduced viral replication and absence of chemotherapy-induced G2 cell cycle arrest. Our results point to the possibility that, at least for OS, virotherapy and chemotherapy should best not be performed simultaneously. In general, our work underscores the importance of testing new genetic anticancer agents and treatment regimens on primary cancer specimens.
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