Publications (2)13.55 Total impact
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Article: KIAA1797/FOCAD encodes a novel focal adhesion protein with tumour suppressor function in gliomas.
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ABSTRACT: In a strategy to identify novel genes involved in glioma pathogenesis by molecular characterization of chromosomal translocation breakpoints, we identified the KIAA1797 gene, encoding a protein with an as yet undefined function, to be disrupted by a 7;9 translocation in a primary glioblastoma culture. Array-based comparative genomic hybridization detected deletions involving KIAA1797 in around half of glioblastoma cell lines and glioblastomas investigated. Quantification of messenger RNA levels in human tissues demonstrated highest KIAA1797 expression in brain, reduced levels in all glioblastoma cell lines and most glioblastomas and similar levels in glial and neuronal cells by analysis of different hippocampal regions from murine brain. Antibodies against KIAA1797 were generated and showed similar protein levels in cortex and subcortical white matter of human brain, while levels were significantly reduced in glioblastomas with KIAA1797 deletion. By immunofluorescence of astrocytoma cells, KIAA1797 co-localized with vinculin in focal adhesions. Physical interaction between KIAA1797 and vinculin was demonstrated via co-immunoprecipitation. Functional in vitro assays demonstrated a significant decrease in colony formation, migration and invasion capacity of LN18 and U87MG glioma cells carrying a homozygous KIAA1797 deletion ectopically expressing KIAA1797 compared with mock-transduced cells. In an in vivo orthotopic xenograft mouse model, U87MG tumour lesions expressing KIAA1797 had a significantly reduced volume compared to tumours not expressing KIAA1797. In summary, the frequently deleted KIAA1797 gene encodes a novel focal adhesion complex protein with tumour suppressor function in gliomas, which we name 'focadhesin'. Since KIAA1797 genetic variation has been implicated in Alzheimer's disease, our data are also relevant for neurodegeneration.Brain 03/2012; 135(Pt 4):1027-41. · 9.46 Impact Factor -
Article: Targeted endothelial gene delivery by ultrasonic destruction of magnetic microbubbles carrying lentiviral vectors.
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ABSTRACT: Site specific vascular gene delivery is a promising tool for treatment of cardiovascular diseases. By combining ultrasound mediated microbubble destruction with site specific magnetic targeting of lentiviruses, we aimed to develop a technique suitable for systemic application. The magnetic nanoparticle coupling to lipid microbubbles was confirmed by absorbance measurements. Association of fluorescent lentivirus to magnetic microbubbles (MMB) was determined by microscopy and flow cytometry. Functionality and efficiency of GFP-encoding lentiviral MMB transduction was evaluated by endothelial (HMEC) GFP expression and cytotoxicity was measured by MTT reduction. Microbubbles with a mean diameter of 4.3 ± 0.04 μm were stable for 2 days, readily magnetizable and magnetically steerable in vitro and efficiently associated with lentivirus. Exposure of eGFP-encoding lentiviral MMB to human endothelial cells followed by application of an external static magnetic field (30 min) and ultrasonic destruction of the microbubbles did not markedly affect cellular viability. Finally, this combination led to a 30-fold increase in transduction efficiency compared to application of naked virus alone. By associating microbubbles with magnetic iron nanoparticles, these function as carriers for lentiviruses achieving tissue specific deposition at the site of interest.Pharmaceutical Research 01/2012; 29(5):1282-94. · 4.09 Impact Factor
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