UMLS:C0001486 - FACTA Search

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Query: UMLS:C0001486 (Adenovirus)
3,125 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Adenovirus DNA is rapidly lost in actively dividing cells. In addition, first-generation (E1-defective) vectors trigger a strong cytotoxicity that impairs the duration of transgene expression. To solve these issues, we have developed a chimeric vector system that uses E1/E4 doubly defective adenoviruses for efficient production of infectious retroviral vectors. The retroviral vector sequences and packaging functions were split into two E1/E3/E4-deleted adenoviral vectors: the Moloney murine leukemia virus gag-pol cistron was expressed from the human EF1 alpha (elongation factor) promoter (AdGAG/POL), whereas the thymidine kinase transgene, embedded in a retroviral vector context, and an amphotropic retroviral envelope cassette were included within a second adenovirus (AdTK/ENV). This chimeric vector system was evaluated with a special emphasis on recombinant retrovirus production in vitro, as well as transgene amplification and persistence in vivo. Retrovirus titers of >10(5) infectious units/mL were routinely obtained in W162 cells coinfected with both recombinant adenoviruses. Long-term transgene persistence (up to 3 months) was demonstrated in vitro in two different cell lines coinfected with AdGAG/POL and AdTK/ENV, and correlated with the detection of specific provirus sequences. A 10- to 50-fold transgene amplification also was demonstrated in an in vivo tumor model infected with the Ad/Rt chimeric vector system. The chimeric vector system described herein combines the efficiency of gene delivery by recombinant adenoviruses with the integrative properties of infectious retroviral vectors. This versatile vector system may open up new avenues for efficient production of oncogenic, but also non-oncogenic, retroviruses from cells of non-murine origin.
Cancer Gene Ther 2000 Aug
PMID:Transgene amplification and persistence after delivery of retroviral vector and packaging functions with E1/E4-deleted adenoviruses. 1097 74

Replicative viral agents represent a novel approach for treating neoplastic disease. Tumor cell killing by the viral agent is achieved by direct consequence of the viral replication. Relative sparing of nontumor is, however, required to provide a therapeutic index of utility for cancer treatment. To this end, an ideal viral agent would, thus, possess several logical attributes, including stability and efficiency for infection and lateral spread in vivo, a preference for replication in tumor versus nontumor cells, and the capability of avoiding early detection-and eradication-by the immune system. To date, none of the agents has exhibited optimal characteristics with regard to the aforementioned attributes. Adenovirus, however, has lent itself to a process of extensive engineering that is dealing with each and every one of the major requirements and that is realizing its clinical potential. An advanced understanding of the cancer phenotype, as well as achievements in functionally exploiting viral plasticity, predicate the design and realization of conditionally replicative adenoviral agents with improved characteristics for cancer therapy.
Clin Cancer Res 2000 Sep
PMID:The development of conditionally replicative adenoviruses for cancer therapy. 1099 20

Adenovirus E1a proteins reverse-transform diverse human tumor cells in culture. This has stimulated interest in the arenas of clinical and basic cancer research. Clinically, cancer gene therapy trials on E1a are in progress, and drug discovery strategies based on E1a are being considered. Biologically, the effect of E1a is unique in that it overrides most or all oncogenic signaling pathways to yield nontumorigenic cells. Apparently, this is a consequence of the ability of E1a to reprogram transcription in tumor cells so as to produce an epithelial phenotype that is refractory to oncogenic growth stimulation. The molecular basis for this effect is emerging.
Adv Cancer Res 2001
PMID:Tumor suppression activity of adenovirus E1a protein: anoikis and the epithelial phenotype. 1103 39

Although the high transfection efficiency with adenovirus in vitro is well documented, it is still not clear whether adenoviral vectors are effective in vivo in solid tumor models. In our preliminary experiment, transduction of tumor tissue was limited to just around the injection site after intratumoral injection of the adenoviral vector. To improve the transduction efficiency in vivo, we tried a combination of adenoviral vector and liposome in our animal model. Adenovirus carrying human placental alkaline phosphatase (AdALP) and Lipofectamine or 1,3-di-oleoyloxy-2-(6-carboxyspermyl)-propylamide were used as a marker gene and the cationic liposome, respectively. A >15-fold increase in the transfection efficiency was observed in CT26 tumor cell lines with the combination of AdALP adenovirus carrying murine granulocyte-macrophage colony-stimulating factor (AdmGM-CSF), and liposome compared with adenovirus alone, showing the feasibility of the combination treatment. In the animal model, with the combination of liposome and AdALP, deeper and wider distribution of the marker gene in the tumor mass was shown. We conclude that the limitations of direct application of adenoviral vectors in a solid tumor model could be overcome by the use of cationic liposomes. This approach will facilitate the more effective delivery of adenoviral vectors in a clinical trial setting.
Cancer Gene Ther 2000 Oct
PMID:Enhancement of adenoviral transduction with polycationic liposomes in vivo. 1105 90

Adenovirus-mediated gene transfer is a novel treatment strategy for head and neck squamous cell carcinoma (HNSCC) that may improve the unacceptable morbidity and mortality associated with conventional treatment. Efficient adenoviral (AdV) infection largely depends on cellular expression of the human coxsackie and adenovirus receptor (hCAR); however, the relatively recent identification of this receptor precludes a comprehensive description of its tissue distribution. We have created tissue culture model systems that approximate the differentiation and three-dimensional structure of stratified squamous epithelium characteristic of head and neck mucosa. Using these systems, we have found that expression of hCAR in native and modeled normal oropharyngeal epithelium decreased as cells differentiated with the most superficial and differentiated cells expressing no detectable hCAR. In contrast, modeled stratified HNSCC cells, which did not differentiate morphologically and did not express cytokeratin markers of differentiation, had equivalent expression of hCAR in superficial and basal layers. The expression of hCAR in our models correlated not only with the undifferentiated state, but also with efficiency of AdV infection. Despite expression of hCAR in underlying basal and suprabasal cells, topical application of AdV to normal modeled epithelium resulted in inefficient transduction of the most superficial cell layer without any infection of underlying cells. These data suggest that in normal epithelium the overlying squamous cells act as a barrier preventing infection of underlying cells that would otherwise be easily infected. In modeled stratified HNSCC, transduction was much more efficient and occurred up to four cell layers deep, suggesting that unlike normal superficial epithelial cells, the superficial cells of stratified HNSCC do not act as an effective barrier to adenoviral infection. The distribution of hCAR in native tissue and the enhanced susceptibility of undifferentiated oropharyngeal epithelial cells, including undifferentiated cancer cells, to AdV infection has important implications for the development of AdV-based targeting strategies for the treatment of head and neck cancer or premalignancies.
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PMID:Efficiency of adenovirus-mediated gene transfer to oropharyngeal epithelial cells correlates with cellular differentiation and human coxsackie and adenovirus receptor expression. 1109 41

Utilization of molecular biology techniques offers attractive options in nuclear medicine for improving cancer imaging and therapy with radiolabeled peptides. Two of these options include utilization of phage-panning to identify novel tumor-specific peptides or single chain antibodies and gene transfer techniques to increase the number of antigen/receptor sites expressed on malignant cells. Our group has focused on the latter approach for improving radiolabeled peptide imaging and therapy. The most widely used gene transfer vectors in clinical gene therapy trials include retrovirus, cationic lipids, and adenovirus. We have utilized adenovirus vectors for gene transfer because of their ability to accomplish efficient in vivo gene transfer. Adenovirus vectors encoding the genes for a variety of antigens/receptors (carcinoembryonic antigen, gastrin-releasing peptide receptor, somatostatin receptor subtype 2 (SSTr2)) have all shown that their expression is increased on cancer cells both in vitro and in vivo following adenovirus infection. Of particular interest has been the adenovirus encoding for SSTr2 (AdCMVSSTr2). Various radioisotopes have been attached to somatostatin analogues for imaging and therapy of SSTr2-positive tumors both clinically and in animal models. The use of these analogues in combination with AdCMVSSTr2 is a promising approach for improving the detection sensitivity and therapeutic efficacy of these radiolabeled peptides against solid tumors. In addition, we have proposed the use of SSTr2 as a marker for imaging the expression of another cancer therapeutic transgene (e.g. cytosine deaminase, thymidine kinase) encoded within the same vector. This would allow for non-invasive monitoring of gene delivery to tumor sites.
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PMID:Gene transfer strategies for improving radiolabeled peptide imaging and therapy. 1110 86

Adenovirus (Ad) efficiently delivers its DNA genome into a variety of cells and tissues, provided that these cells express appropriate receptors, including the coxsackie-adenovirus receptor (CAR), which binds to the terminal knob domain of the viral capsid protein fiber. To render CAR-negative cells susceptible to Ad infection, we have produced a bispecific hybrid adapter protein consisting of the amino-terminal extracellular domain of the human CAR protein (CARex) and the Fc region of the human immunoglobulin G1 protein, comprising the hinge and the CH2 and CH3 regions. CARex-Fc was purified from COS7 cell supernatants and mixed with Ad particles, thus blocking Ad infection of CAR-positive but Fc receptor-negative cells. The functionality of the CARex domain was further confirmed by successful immunization of mice with CARex-Fc followed by selection of a monoclonal anti-human CAR antibody (E1-1), which blocked Ad infection of CAR-positive cells. When mixed with Ad expressing eGFP, CARex-Fc mediated an up to 250-fold increase of transgene expression in CAR-negative human monocytic cell lines expressing the high-affinity Fcgamma receptor I (CD64) but not in cells expressing the low-affinity Fcgamma receptor II (CD32) or III (CD16). These results open new perspectives for Ad-mediated cancer cell vaccination, including the treatment of acute myeloid leukemia.
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PMID:Functional and selective targeting of adenovirus to high-affinity Fcgamma receptor I-positive cells by using a bispecific hybrid adapter. 1111 16

High frequency of p16 alteration and high local recurrence rate of bladder cancer make this cancer an ideal target for p16 gene therapy. However, a low transduction rate of p16 via adenoviral vector causes an inconsistent result. In this study, we have tested adenovirus-p16 in several bladder cancer cell lines and investigated a way of improving the low transduction rate. Adenovirus-p16 showed a strong antitumor effect on bladder cancer cell lines (253J and T24) with strong Coxackie-adenoviral receptor (CAR) expression but little antitumor effect on bladder cancer cell lines (J82 and HT1376) with little CAR expression. In this study, we suggest a simple way of overcoming the differential effects of the adenovirus. The addition of butyrate to media was found to increase the transduction rate of adenovirus remarkably and increase the antitumor effect of adenovirus-p16 in bladder cancer cell lines with little CAR expression. Butyrate effects were related with increased CAR expression on the cell surface as well as increased transgene expression from adenoviral vector. From these observations, application of adenovirus-p16 gene therapy with butyrate can overcome the obstacle of low gene transfer and enhance the antitumor effect of adenovirus-p16 in bladder cancer.
Clin Cancer Res 2001 Jan
PMID:Differential effects of adenovirus-p16 on bladder cancer cell lines can be overcome by the addition of butyrate. 1120 11

Adenovirus E4orf4 protein is a multifunctional viral regulator that induces p53-independent apoptosis in transformed cells, but not in normal cells. E4orf4-induced apoptosis can occur without activation of known caspases, although E4orf4 induces caspase activity in some cell lines. The interaction of E4orf4 with a specific subpopulation of protein phosphatase 2A (PP2A) molecules that contain B subunits, but not with those that contain B' subunits, is required for induction of apoptosis. This review suggests the potential use of E4orf4 in cancer therapy, and discusses whether E4orf4-induced apoptosis plays a role in the viral life cycle. Future research directions are also highlighted.
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PMID:Induction of apoptosis by adenovirus E4orf4 protein. 1122 41

The purpose of this study was to determine the efficacy of adenovirus-based p53 gene therapy in the treatment of ovarian cancer using an intraperitoneal microscopic tumor animal model system. Adenovirus-mediated wild-type p53 gene was introduced into the NIH:OVCAR-3 human ovarian cancer cell line in vitro and in vivo. In order to study microscopic intraperitoneal tumor, athymic nude mice were inoculated intraperitoneally (i.p.) with 1 x 107 OVCAR-3 cells and observed for tumor growth. Three days after inoculation with OVCAR-3 cells, the mice were divided into 3 treatment groups. One group received three daily i.p. injections of 1 x 108 pfu Ad-CMV-p53, a second group received three daily i.p. injection of 1 x 108 pfu of the control adenovirus construct expressing beta galactosidase (Ad-CMV-betagal) and a third group received three daily i.p. injections of normal saline. Adenovirus-mediated introduction of the wild-type p53 gene in the ovarian cancer cell line resulted in transient high levels of p53 protein for 24-48 h. Cell cycle analysis revealed G1 arrest, as well as the appearance of apoptosis. In vitro cell growth assays showed growth inhibition of cancer cells infected with Ad-CMV-p53 compared to cells infected with Ad-CMV-betagal or normal saline. There was a significant increase in survival in the Ad-CMV-p53 adenovirus treated animals compared to the PBS treated animals (P = 0.004). Likewise, the survival in Ad-CMV-p53 treated mice was also significantly greater than mice treated with Ad-CMV-betagal (P < 0.0001). These results demonstrated that Ad-CMV-p53 treatment is effective in inhibiting tumor growth and prolonging survival in this microscopic cancer xenograft model. The results of this study constitute a step in translating promising in vitro and in vivo data from an adenovirus-based gene therapeutic model system into practical and scientifically based human cancer therapeutic trials.
Int J Gynecol Cancer 1999 Sep
PMID:Efficacy of intraperitoneal adenovirus-mediated p53 gene therapy in ovarian cancer. 1124 Jul 95

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