Your search keyword '"Menzel, Uwe"' showing total 3 results

1. Global Transcriptional Response of Human Liver Cells to Ethanol Stress of Different Strength Reveals Hormetic Behavior.

Author

Schmidt‐Heck, Wolfgang, Wönne, Eva C., Hiller, Thomas, Menzel, Uwe, Koczan, Dirk, Damm, Georg, Seehofer, Daniel, Knöspel, Fanny, Freyer, Nora, Guthke, Reinhard, Dooley, Steven, and Zeilinger, Katrin

Subjects

HEPATITIS, COMPLICATIONS of alcoholism, PHYSIOLOGICAL adaptation, ALGORITHMS, ARTIFICIAL intelligence, CARBOXYLIC acids, CELL culture, CELLULAR signal transduction, DOSE-effect relationship in pharmacology, ETHANOL, GENE expression, HUMAN anatomical models, KETONES, LIVER, PHYSIOLOGICAL stress, IN vitro studies, EPIGENOMICS, GENETICS

Abstract

Background The liver is the major site for alcohol metabolism in the body and therefore the primary target organ for ethanol (EtOH)-induced toxicity. In this study, we investigated the in vitro response of human liver cells to different EtOH concentrations in a perfused bioartificial liver device that mimics the complex architecture of the natural organ. Methods Primary human liver cells were cultured in the bioartificial liver device and treated for 24 hours with medium containing 150 mM (low), 300 mM (medium), or 600 mM (high) EtOH, while a control culture was kept untreated. Gene expression patterns for each EtOH concentration were monitored using Affymetrix Human Gene 1.0 ST Gene chips. Scaled expression profiles of differentially expressed genes (DEGs) were clustered using Fuzzy c-means algorithm. In addition, functional classification methods, KEGG pathway mapping and also a machine learning approach (Random Forest) were utilized. Results A number of 966 (150 mM EtOH), 1,334 (300 mM EtOH), or 4,132 (600 mM EtOH) genes were found to be differentially expressed. Dose-response relationships of the identified clusters of co-expressed genes showed a monotonic, threshold, or nonmonotonic (hormetic) behavior. Functional classification of DEGs revealed that low or medium EtOH concentrations operate adaptation processes, while alterations observed for the high EtOH concentration reflect the response to cellular damage. The genes displaying a hormetic response were functionally characterized by overrepresented 'cellular ketone metabolism' and 'carboxylic acid metabolism.' Altered expression of the genes BAHD1 and H3F3B was identified as sufficient to classify the samples according to the applied EtOH doses. Conclusions Different pathways of metabolic and epigenetic regulation are affected by EtOH exposition and partly undergo hormetic regulation in the bioartificial liver device. Gene expression changes observed at high EtOH concentrations reflect in some aspects the situation of alcoholic hepatitis in humans. [ABSTRACT FROM AUTHOR]

Published

2017

2. Extension of Life Span by Impaired Glucose Metabolism in Caenorhabditis elegans Is Accompanied by Structural Rearrangements of the Transcriptomic Network.

Author

Priebe, Steffen, Menzel, Uwe, Zarse, Kim, Groth, Marco, Platzer, Matthias, Ristow, Michael, and Guthke, Reinhard

Subjects

*GLUCOSE metabolism, *CAENORHABDITIS elegans, *LIFE spans, *MICROBIAL metabolism, *NEMATODE genetics, *CELLULAR signal transduction, *GENE expression, *NEMATODES, *MICROORGANISMS

Abstract

Glucose restriction mimicked by feeding the roundworm Caenorhabditis elegans with 2-deoxy-D-glucose (DOG) - a glucose molecule that lacks the ability to undergo glycolysis - has been found to increase the life span of the nematodes considerably. To facilitate understanding of the molecular mechanisms behind this life extension, we analyzed transcriptomes of DOG-treated and untreated roundworms obtained by RNA-seq at different ages. We found that, depending on age, DOG changes the magnitude of the expression values of about 2 to 24 percent of the genes significantly, although our results reveal that the gross changes introduced by DOG are small compared to the age-induced changes. We found that 27 genes are constantly either up- or down-regulated by DOG over the whole life span, among them several members of the cytochrome P450 family. The monotonic change with age of the temporal expression patterns of the genes was investigated, leading to the result that 21 genes reverse their monotonic behaviour under impaired glycolysis. Put simply, the DOG-treatment reduces the gross transcriptional activity but increases the interconnectedness of gene expression. However, a detailed analysis of network parameters discloses that the introduced changes differ remarkably between individual signalling pathways. We found a reorganization of the hubs of the mTOR pathway when standard diet is replaced by DOG feeding. By constructing correlation based difference networks, we identified those signalling pathways that are most vigorously changed by impaired glycolysis. Taken together, we have found a number of genes and pathways that are potentially involved in the DOG-driven extension of life span of C. elegans. Furthermore, our results demonstrate how the network structure of ageing-relevant signalling pathways is reorganised under impaired glycolysis. [ABSTRACT FROM AUTHOR]

Published

2013

3. Longitudinal RNA-Seq Analysis of Vertebrate Aging Identifies Mitochondrial Complex I as a Small-Molecule-Sensitive Modifier of Lifespan

Author

Michael Ristow, Marco Groth, Steffen Priebe, Nils Hartmann, Matthias Platzer, Philipp Koch, Uwe Menzel, Reinhard Guthke, Mario Baumgart, Luca Pandolfini, Alessandro Cellerino, Christoph Englert, Marius Felder, Baumgart, Mario, Priebe, Steffen, Groth, Marco, Hartmann, Nil, Menzel, Uwe, Pandolfini, Luca, Koch, Philipp, Felder, Mariu, Ristow, Michael, Englert, Christoph, Guthke, Reinhard, Platzer, Matthia, Cellerino, Alessandro, Pandolfini, Luca [0000-0003-1444-8167], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, lifespan regulation, Histology, mitohormesis, rejuvenation, weighted gene coexpression network analysis (WGCNA), RNA-Seq, history trait, Settore BIO/09 - Fisiologia, Pathology and Forensic Medicine, Nothobranchius furzeri, Aging, GAGE, History trait, Hormesis, Hourglass, Life ribosome, Lifespan regulation, Longevity, Longitudinal study, Mitohormesis, Rejuvenation, RNA transport, RNA-seq, Weighted gene coexpression network analysis (WGCNA), Zebrafish, Cyprinodontiformes, 03 medical and health sciences, 0302 clinical medicine, longevity, hormesis, Gene expression, Animals, Mitochondrial respiratory chain complex I, Longitudinal Studies, Genetic variability, Gene, mitohormesi, Regulation of gene expression, Genetics, biology, Sequence Analysis, RNA, hourgla, aging, longitudinal study, life ribosome, zebrafish, hourglass, Cell Biology, biology.organism_classification, hormesi, Settore BIO/18 - Genetica, 030104 developmental biology, Vertebrates, RNA, 030217 neurology & neurosurgery

Abstract

Mutations and genetic variability affect gene expression and lifespan, but the impact of variations in gene expression within individuals on their aging-related mortality is poorly understood. We performed a longitudinal study in the short-lived killifish, Nothobranchius furzeri, and correlated quantitative variations in gene expression during early adult life with lifespan. Shorter- and longer-lived individuals differ in their gene expression before the onset of aging-related mortality; differences in gene expression are more pronounced early in life. We identified mitochondrial respiratory chain complex I as a hub in a module of genes whose expression is negatively correlated with lifespan. Accordingly, partial pharmacological inhibition of complex I by the small molecule rotenone reversed aging-related regulation of gene expression and extended lifespan in N. furzeri by 15%. These results support the use of N. furzeri as a vertebrate model for identifying the protein targets, pharmacological modulators, and individual-to-individual variability associated with aging., Cell Systems, 2 (2), ISSN:2405-4720