Your search keyword '"L. Esch"' showing total 7 results

1. Identification of variables affecting metabolic estrogen‐DNA adduct fluxes in human glandular breast tissues

Author

Peter Eckert, Katja Schmalbach, Daniela Pemp, Thomas Dandekar, Carolin Kleider, Leo N. Geppert, René Hauptstein, Claudia Köllmann, Iva Neshkova, Alexander Cecil, Leane Lehmann, Benjamin Spielmann, Juliane Wunder, and Harald L. Esch

Subjects

Biochemistry, Estrogen, medicine.drug_class, Chemistry, DNA adduct, medicine, Identification (biology)

Published

2020

2. 2,4‐Hexadienal but not 2,4‐heptadien‐6‐one shows DNA base reactivity despite previous conjugation to glutathione

Author

Harald L. Esch, M. Meier, Carolin Kleider, and Leane Lehmann

Subjects

chemistry.chemical_compound, Chemistry, Stereochemistry, Reactivity (chemistry), Glutathione, Base (exponentiation), DNA

Published

2020

3. To B. or Not to B.?: The B. Schools Under Attack-Again?

Author

L. Esch, J. Sagebien, and K. Melenchuk

Subjects

Marketing, Public Administration, Management of Technology and Innovation, Business and International Management

Abstract

A thorough, albeit not exhaustive, survey was conducted of the current literature on worldwide megatrends, the impact of these trends on the business community, and the ability of current business education programs to educate future managers. The paper summarizes the research findings and the views of business leaders, futurists, and academics. The key concern is to understand why, in spite of several decades of strident calls for immediate change, the necessary (even though radical) changes have not occurred. The paper discusses some of the obstacles to change and offers some implications to educators. Resume On a fait un examen approfondi, sans toutefois etre exhaustif. de la litterature actuelle portant sur les vagues de fond qui secernent la planete. des consequences de ces tendances sur les entreprises et sur la capacite des programmes en sciences administratives presentement en vigueur de former les cadres de l'avenir. Cet article contient un resume des resultats de la recherche, les opinions de chefs d'entreprise, de futurologues et d'universitaires. La question defond est de comprendre pourquoi. apres tant d'annees d'appels incessants a des changements urgents. les modifications necessaires. tout en admettant qu'elles soient radicates, ne se sont toujours pas produites. On trouve dans cet article une discussion sur quelques-uns des obstacles au changement et quelques implications pour les educateurs.

Published

2009

4. Posters

Author

F. Dal Bello, J. Walter, C. Hertel, W. P Hammes, G. Festag, N. Haag, Gabriele Beyer‐Sehlmeyer, M. N. Ebert, B. Marian, Eva Gietl, Annett Klinder, Stella Pistoli, R. Goralczyk, H. Bachmann, G. Riss, C‐P. Aebischer, B. Lenz, A. Kampkötter, E. Röhrdanz, K. Iwami, S. Ohler, W. Wätjen, Y. Chovolou, S. E. Kulling, R. Kahl, D. Kavvadias, P. Sand, P. Riederer, E. Richling, P. Schreier, Peter P. Hoppe, Klaus Kraemer, Henk van den Berg, Gery Steenge, Trinette van Vliet, S. Lebrun, H. Schulze, W. Föllmann, Leane Lehmann, P. Niering, I. Köhler, Q.‐H. Tran‐Thi, Erika Pfeiffer, Harald L. Esch, Simone Höhle, Aniko M. Solyom, Barbara N. Timmermann, Manfred Metzler, W. Seefelder, N. Bartke, T. Gronauer, S. Fischer, H.‐U. Humpf, S. Schäfer, H.G. Kamp, C. Müller, B. Haber, G. Eisenbrand, C. Janzowski, K. Wertz, P. Buchwald, T. Hansen, M. Niehof, M. Dangers, J. Borlak, Stefanie Klenow, Michael Glei, Bernd Haber, Beatrice L. Pool‐Zobel, Annette Baumgart, Melanie Schmidt, Hans‐Joachim Schmitz, Dieter Schrenk, Achim Bub, Bernhard Watzl, M. Roller, G. Caderni, G. Rechkemmer, Karlis Briviba, Kerstin Schnäbele, Elke Schwertle, Kerstin Rebscher, Stephan W. Barth, Silvia Roser, Heike Lang, Anette Höll, Sabine Guth, Doris Marko, Monika Kemény, Michael Habermeyer, Edda Bernardy, Susanne Meiers, and Ulrike Weyand

Published

2004

5. Localization of a putative liver tumor suppressor locus to a 950-kb region of human 11p11.2-p12 using rat liver tumor microcell hybrid cell lines

Author

Bernard E. Weissman, Kristen M. Borchert, Gary J. Smith, Karen D. McCullough, Gwyn L. Esch, Laura H. Reid, Joe W. Grisham, and William B. Coleman

Subjects

Cancer Research, Candidate gene, Liver tumor, Positional cloning, Chromosome, Locus (genetics), Biology, medicine.disease, Molecular biology, law.invention, Metastasis Suppressor Gene, law, Chromosomal region, medicine, Suppressor, Molecular Biology

Abstract

We previously demonstrated that a locus (or loci) linked to the D11S436 marker, which is within the approximately 6-Mb cen-p12 region of human chromosome 11, suppresses the tumorigenic potential of some rat liver epithelial tumor microcell hybrid (MCH) cell lines. To more precisely map this putative liver tumor suppressor locus, we examined 25 loci from human chromosome 11 in suppressed MCH cell lines. Detailed analysis of these markers revealed a minimal area of overlap among the suppressed MCH cell lines corresponding to the chromosomal region bounded by (but not including) microsatellite markers D11S1319 and D11S1958E and containing microsatellite markers D11S436, D11S554, and D11S1344. Direct examination of the kang ai 1 (KAI1) prostatic adenocarcinoma metastasis suppressor gene (which is closely linked to D11S1344) produced evidence suggesting that this locus was not responsible for tumor suppression in this model system. In addition, our data strongly suggested that the putative liver tumor suppressor locus was distinct from other known 11p tumor suppressor loci, including the multiple exotoses 2 locus (at 11p11.2-p12), Wilms' tumor 1 locus (at 11p13), and Wilms' tumor 2 locus (at 11p15.5). The results of this study significantly narrowed the chromosomal location of the putative liver tumor suppressor locus to a region of human 11p11.2-p12 that is approximately 950 kb. This advance forms the basis for positional cloning of candidate genes from this region and, in addition, identified a number of chromosomal markers that will be useful for determining the involvement of this locus in the pathogenesis of human liver cancer. Mol. Carcinog. 19:267–272, 1997. © 1997 Wiley-Liss, Inc.

Published

1997

6. Suppression of the tumorigenic phenotype of a rat liver epithelial tumor cell line by the p11.2–p12 region of human chromosome 11

Author

Chris J. Civalier, Bernard E. Weissman, Gary J. Smith, Gwyn L. Esch, William B. Coleman, Elizabeth Livanos, Karen D. McCullough, and Joe W. Grisham

Subjects

Genetic Markers, Cancer Research, Molecular Sequence Data, Locus (genetics), Hybrid Cells, In Vitro Techniques, Biology, law.invention, law, Centromere, Tumor Cells, Cultured, Animals, Humans, Genes, Tumor Suppressor, Neoplastic transformation, Molecular Biology, Gene, In Situ Hybridization, Fluorescence, DNA Primers, Base Sequence, Chromosomes, Human, Pair 11, Liver Neoplasms, Chromosome Mapping, Chromosome, Neoplasms, Experimental, Phenotype, Molecular biology, Rats, Inbred F344, Rats, Cell culture, Suppressor, Chromosome Deletion

Abstract

Comparative chromosomal mapping studies and investigations of tumor-associated chromosomal abnormalities suggest that the development of hepatic tumors in humans and rats may share a common molecular mechanism that involves inactivation of the same tumor suppressor genes or common genetic loci. We investigated the potential of human chromosomes 2 and 11 to suppress the tumorigenic phenotype of rat liver epithelial tumor cell lines. These tumor cell lines (GN6TF and GP7TB) display elevated saturation densities in culture, efficiently form colonies in soft agar, and produce subcutaneous tumors in 100% of syngeneic rat hosts with short latency periods. Introduction of human chromosome 11 by microcell fusion markedly altered the tumorigenicity and the transformed phenotype of GN6TF cells. In contrast, the tumorigenic potential and phenotype of GP7TB cells was unaffected by the introduction of human chromosome 11, indicating that not all rat liver tumor cell lines can be suppressed by loci carried on this chromosome. Introduction of human chromosome 2 had little or no effect on the tumorigenicity or cellular phenotype of either tumor cell line, suggesting the involvement of chromosome 11–specific loci in the suppression of the GN6TF tumor cell line. The GN6TF-11neo microcell hybrid cell lines displayed significantly reduced saturation densities in monolayer cultures, and their ability to grow in soft agar was completely inhibited. Although GN6TF-11neo cells ultimately formed tumors in 80–100% of syngeneic rat hosts, the latency period for tumor formation was much longer. Molecular characterization of GN6TF-11neo microcell hybrid cell lines indicated that some of the clonal lines had spontaneously lost significant portions of the introduced human chromosome, partially delineating the chromosomal location of the putative tumor suppressor locus to the region between the centromere and 11p12. Molecular examination of microcell hybrid–derived tumor cell lines further defined the minimal portion of human chromosome 11 capable of tumor suppression in this model system to the region 11p11.2-p12. © 1995 Wiley-Liss, Inc.

Published

1995

7. Platelets, endothelial cells and leukocytes contribute to the exercise-triggered release of extracellular vesicles into the circulation.

Author

Brahmer A, Neuberger E, Esch-Heisser L, Haller N, Jorgensen MM, Baek R, Möbius W, Simon P, and Krämer-Albers EM

Abstract

Physical activity initiates a wide range of multi-systemic adaptations that promote mental and physical health. Recent work demonstrated that exercise triggers the release of extracellular vesicles (EVs) into the circulation, possibly contributing to exercise-associated adaptive systemic signalling. Circulating EVs comprise a heterogeneous collection of different EV-subclasses released from various cell types. So far, a comprehensive picture of the parental and target cell types, EV-subpopulation diversity and functional properties of EVs released during exercise (ExerVs) is lacking. Here, we performed a detailed EV-phenotyping analysis to explore the cellular origin and potential subtypes of ExerVs. Healthy male athletes were subjected to an incremental cycling test until exhaustion and blood was drawn before, during, and immediately after the test. Analysis of total blood plasma by EV Array suggested endothelial and leukocyte characteristics of ExerVs. We further purified ExerVs from plasma by size exclusion chromatography as well as CD9-, CD63- or CD81-immunobead isolation to examine ExerV-subclass dynamics. EV-marker analysis demonstrated increasing EV-levels during cycling exercise, with highest levels at peak exercise in all EV-subclasses analysed. Phenotyping of ExerVs using a multiplexed flow-cytometry platform revealed a pattern of cell surface markers associated with ExerVs and identified lymphocytes (CD4, CD8), monocytes (CD14), platelets (CD41, CD42, CD62P), endothelial cells (CD105, CD146) and antigen presenting cells (MHC-II) as ExerV-parental cells. We conclude that multiple cell types associated with the circulatory system contribute to a pool of heterogeneous ExerVs, which may be involved in exercise-related signalling mechanisms and tissue crosstalk.

Published

2019