Multicolor fluorescence in situ hybridization on metaphase chromosomes and interphase Halo-preparations using cosmid and YAC clones for the simultaneous high resolution mapping of deletions in the dystrophin gene

We report on multicolor fluorescence in situ hybridization protocols for the simultaneous visualization of deletion-prone regions for carrier detection of Duchenne/ Becker (DMD/BMD) muscular dystrophy. Cosmid and yeast artificial chromosome (YAC) clones specific for preferentially deleted subregions of the dystrophin gene were labeled differentially and detected with three different fluorochromes using digital imaging microscopy. This approach allows for an assessment of the carrier status of female relatives even in families where no index patient is available. Cosmid and YAC clones, and different probe-generation protocols are compared with respect to their feasibility for carrier detection. The use of histone-depleted interphase nuclei (Halo-preparations) for deletion mapping is demonstrated and shown to have a resolution power of 5 kb

Mapping of Multiple DNA Gains and Losses in Primary Small Cell Lung Carcinomas by Comparative Genomic Hybridization

Comparative genomic hybridization was applied for a comprehensive screening of under- and overrepresentation of genetic material in 13 autoptic small cell lung cancer specimens. The most abundant genetic changes include DNA losses of chromosome arms 3p, 5q, 10q, 13q, and 17p and DNA gains of 3q, 5p, 8q, and 17q. Amplification sites in these tumors were mapped to 22 chromosome bands. The most frequently involved band was 19q13.1 (4 cases). Bands 1p32, 2p23, 7q11.2, 8q24, and 13q33–34 were involved in two cases each

Molecular cytogenetic analysis of formalin-fixed, paraffin-embedded solid tumors by comparative genomic hybridization after universal DNA-amplification

We present a technique which allows the detection and chromosomal localization of DNA sequence copy number changes in solid tumor genomes from frozen sections and paraffin embedded, formalin fixed specimens. Based on comparative genomic hybridization and on universal DNA amplification procedures this technique is possible even if only a few tumor cells are available. We demonstrate the feasibility of this method to visualize complete and partial chromosome gains and losses and gene amplifications In archived solid tumor samples

3D-Voronoi Diagramme zur quantitativen Bildanalyse in der Interphase-Cytogenetik

Um die Anordnung von Chromosomen in Zellkernen der Interphase zu untersuchen, wurde ein Verfahren aus der Computergeometrie adaptiert. Dieser Ansatz basiert auf der Zerlegung von dreidimensionalen Bildvolumen mithilfe des Voronoi-Diagramms in konvexe Polyeder. Die graphenorientierte, geometrische Struktur dieses Verfahrens ermöglicht sowohl eine schnelle Extraktion von Objekten im Bildraum als auch die Berechnung morphologischer Parameter wie Volumina, Oberflächen und Rundheitsfaktoren. In diesem Beitrag wird exemplarisch die dreidimensionale Morphologie von XChromosomen in weiblichen Interphasezellkernen mithilfe dieser drei Parameter untersucht. Um diese Zellkerne mit lichtoptischen Methoden zu untersuchen, wurden die Territorien der X-Chromosomen mit einem molekularcytogenetischen Verfahren fluoreszierend dargestellt. Zur Unterscheidung des aktiven und inaktiven X-Chromosoms wurde das Barr-Körperchen zusätzlich markiert und mithilfe eines Epifluoreszenzmikroskops, ausgerüstet mit einer CCD-Kamera, aufgenommen. Anschließend wurden 1 2 - 2 5 äquidistante, lichtoptische Schnitte der X-Chromosomenterritorien mit einem konfokalen Laser Scanning Mikroskop (CLSM) aufgenommen. Diese lichtoptischen Schnitte wurden mithilfe des Voronoi-Verfahrens segmentiert und analysiert. Methoden aus der Computergraphik wurden zur Visualisierung der Ergebnisse eingesetzt. Es konnte gezeigt werden, daß mithilfe des Voronoi-Verfahrens Chromosomen- Territorien anhand der morphologischen Parameter zuverlässig beschrieben werden können

Mutant IDH1 Differently Affects Redox State and Metabolism in Glial Cells of Normal and Tumor Origin

IDH1R132H (isocitrate dehydrogenase 1) mutations play a key role in the development of low-grade gliomas. IDH1wt converts isocitrate to α-ketoglutarate while reducing nicotinamide adenine dinucleotide phosphate (NADP+), whereas IDH1R132H uses α-ketoglutarate and NADPH to generate the oncometabolite 2-hydroxyglutarate (2-HG). While the effects of 2-HG have been the subject of intense research, the 2-HG independent effects of IDH1R132H are still ambiguous. The present study demonstrates that IDH1R132H expression but not 2-HG alone leads to significantly decreased tricarboxylic acid (TCA) cycle metabolites, reduced proliferation, and enhanced sensitivity to irradiation in both glioblastoma cells and astrocytes in vitro. Glioblastoma cells, but not astrocytes, showed decreased NADPH and NAD+ levels upon IDH1R132H transduction. However, in astrocytes IDH1R132H led to elevated expression of the NAD-synthesizing enzyme nicotinamide phosphoribosyltransferase (NAMPT). These effects were not 2-HG mediated. This suggests that IDH1R132H cells utilize NAD+ to restore NADP pools, which only astrocytes could compensate via induction of NAMPT. We found that the expression of NAMPT is lower in patient-derived IDH1-mutant glioma cells and xenografts compared to IDH1-wildtype models. The Cancer Genome Atlas (TCGA) data analysis confirmed lower NAMPT expression in IDH1-mutant versus IDH1-wildtype gliomas. We show that the IDH1 mutation directly affects the energy homeostasis and redox state in a cell-type dependent manner. Targeting the impairments in metabolism and redox state might open up new avenues for treating IDH1-mutant gliomas.publishedVersio

Optimizing Genetic Workup in Pheochromocytoma and Paraganglioma by Integrating Diagnostic and Research Approaches

Pheochromocytomas and paragangliomas (PPGL) are rare neuroendocrine tumors with a strong hereditary background and a large genetic heterogeneity. Identification of the underlying genetic cause is crucial for the management of patients and their families as it aids differentiation between hereditary and sporadic cases. To improve diagnostics and clinical management we tailored an enrichment based comprehensive multi-gene next generation sequencing panel applicable to both analyses of tumor tissue and blood samples. We applied this panel to tumor samples and compared its performance to our current routine diagnostic approach. Routine diagnostic sequencing of 11 PPGL susceptibility genes was applied to blood samples of 65 unselected PPGL patients at a single center in Dresden, Germany. Predisposing germline mutations were identified in 19 (29.2%) patients. Analyses of 28 PPGL tumor tissues using the dedicated PPGL panel revealed pathogenic or likely pathogenic variants in known PPGL susceptibility genes in 21 (75%) cases, including mutations in IDH2, ATRX and HRAS. These mutations suggest sporadic tumor development. Our results imply a diagnostic benefit from extended molecular tumor testing of PPGLs and consequent improvement of patient management. The approach is promising for determination of prognostic biomarkers that support therapeutic decision-making.Acknowledgments: We thank the patients and their families who have made this research possible. We want to thank JacquesW. Lenders for his support. We further thank Alexander Krüger, Lydia Rossow and Franziska Stübner for technical support as well as Katharina Langton and Uwe Siemon for their assistance in patient administration.S