Maaike Everts scite author profile

In chronic inflammatory diseases, the endothelium is an attractive target for pharmacological intervention because it plays an important role in leukocyte recruitment. Hence, inhibition of endothelial cell activation and consequent leukocyte infiltration may improve therapeutic outcome in these diseases. We report on a drug targeting strategy for the selective delivery of the anti-inflammatory drug dexamethasone to activated endothelial cells, using an E-selectin-directed drug-Ab conjugate. Dexamethasone was covalently attached to an anti-E-selectin Ab, resulting in the so-called dexamethasone-anti-E-selectin conjugate. Binding of the conjugate to E-selectin was studied using surface plasmon resonance and immunohistochemistry. Furthermore, internalization of the conjugate was studied using confocal laser scanning microscopy and immuno-transmission electron microscopy. It was demonstrated that the dexamethasone-anti-E-selectin conjugate, like the unmodified anti-E-selectin Ab, selectively bound to TNF-α-stimulated endothelial cells and not to resting endothelial cells. After binding, the conjugate was internalized and routed to multivesicular bodies, which is a lysosome-related cellular compartment. After intracellular degradation, pharmacologically active dexamethasone was released, as shown in endothelial cells that were transfected with a glucocorticoid-responsive reporter gene. Furthermore, intracellularly delivered dexamethasone was able to down-regulate the proinflammatory gene IL-8. In conclusion, this study demonstrates the possibility to selectively deliver the anti-inflammatory drug dexamethasone into activated endothelial cells, using an anti-E-selectin Ab as a carrier molecule.

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Fluorescently Labeled Adenovirus with pIX-EGFP for Vector Detection

Everts

Dmitriev

et al. 2004

Mol Imaging

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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.

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Transductional Targeting of Adenoviral Cancer Gene Therapy

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Curiel

2004

CGT

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Adenoviral gene therapy has shown promise in both preclinical and clinical settings, but several hurdles need to be overcome before it can reach its full therapeutic potential. One such hurdle is the need for targeting the right cell type, while avoiding liver uptake and hence side effects. This review will focus on transductional targeting strategies, in which the adenoviral particle is physically targeted to specific surface receptors expressed on the target cell. This can be achieved by using either bifunctional adaper molecules, which bind to the adenoviral particle on one side and to the targeted receptor on the other, or genetic targeting strategies. Adapter molecules comprise both chemically conjugated targeting moieties and recombinant fusion proteins, the latter having the advantage of being a homogeneous population. Genetic retargeting strategies include fiber or fiber knob chimerism, genetic incorporation of targeting ligands in the fiber or other capsid locales, or a combination of both ('complex mosaics'). Since sequestration of virions in the liver presents a major problem for the therapeutic utility of adenoviral gene therapy after systemic administration, blockade of liver uptake has become an increased area of investigation. Strategies encompass blockade of the adenovirus interaction with its cognate receptor CAR, by either using the soluble ectodomain of CAR, or ablation of CAR-interacting amino acid residues in the fiber knob. In addition, inhibition of interaction with additional adenovirus receptors, such as integrins or heparan sulphate proteoglycans, hold promise for decreasing liver uptake and hence adenoviral toxicity.

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Preclinical evaluation of transcriptional targeting strategies for carcinoma of the breast in a tissue slice model system

et al. 2005

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Introduction In view of the limited success of available treatment modalities for metastatic breast cancer, alternative and complementary strategies need to be developed. Adenoviral vector mediated strategies for breast cancer gene therapy and virotherapy are a promising novel therapeutic platform for the treatment of breast cancer. However, the promiscuous tropism of adenoviruses (Ads) is a major concern. Employing tissue specific promoters (TSPs) to restrict transgene expression or viral replication is an effective way to increase specificity towards tumor tissues and to reduce adverse effects in non-target tissues such as the liver. In this regard, candidate breast cancer TSPs include promoters of the genes for the epithelial glycoprotein 2 (EGP-2), cyclooxygenase-2 (Cox-2), α-chemokine SDF-1 receptor (stromal-cell-derived factor, CXCR4), secretory leukoprotease inhibitor (SLPI) and survivin.

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Gene transfer to carcinoma of the breast with fiber-modified adenoviral vectors in a tissue slice model system

Stoff-Khalili

Stoff²,

Rivera

et al. 2005

Cancer Biology & Therapy

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Successful adenoviral (Ad) vector-mediated strategies for breast cancer gene therapy and virotherapy have heretofore been hindered by low transduction efficiency. This has recently been understood to result from a relative paucity of expression of the primary adenovirus receptor, coxsackie-adenovirus-receptor (CAR), on primary tumor cells. To further investigate this issue, we evaluated the expression of CAR on breast cancer cell lines as well as primary breast cancer cells. With the exception of one patient sample, CAR expression was notably higher in the tumor cells from patients compared to CAR expression in the tumor cell lines. Furthermore, we explored CAR-independent targeting strategies to breast cancer tissue by exploring a panel of infectivity-enhanced Ad vectors, which contain CAR-independent targeting motifs for their utility in breast cancer gene therapy and virotherapy. These targeting motifs included Ad 3 knob (Ad5/3), canine Ad serotype 2 knob (Ad5CAV-2), RGD (Ad5.RGD), polylysine (Ad5.pK7), or both RGD and polylysine (Ad5.RGD.pK7), and were tested using the breast cancer tissue slice model, which is the most stringent substrate system available. Of all the tested tropism modified Ad vectors, Ad5/3 exhibited the highest transductional efficiency in breast cancer. These preclinical results suggest that Ad5/3 is the most useful modification to achieve higher clinical efficacy of breast cancer gene therapy and virotherapy.

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Maaike Everts

Selective Intracellular Delivery of Dexamethasone into Activated Endothelial Cells Using an E-Selectin-Directed Immunoconjugate

Fluorescently Labeled Adenovirus with pIX-EGFP for Vector Detection

Transductional Targeting of Adenoviral Cancer Gene Therapy

Preclinical evaluation of transcriptional targeting strategies for carcinoma of the breast in a tissue slice model system

Gene transfer to carcinoma of the breast with fiber-modified adenoviral vectors in a tissue slice model system

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