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Project description:Mechanical feedback from the tumor microenvironment regulates an array of processes underlying cancer biology. Routine culture and adaptation of cancer cell lines to unnaturally rigid plastic or glass substrates leads to profound changes in their growth, metastatic potential and potentially chemotherapeutic response. Microarray studies were conducted to probe the impact of substratum stiffness on the regulation of genetic pathways in mammary tumor cells, and immortalized cancer cell lines, that modulate sensitivity and resistance towards clinically-approved chemotherapeutics We used microarrays to detail the global programme of gene expression underlying cellular response to substrates of different mechanical stiffness.

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Project description:High energy intake and, specifically, high dietary fat intake challenges the mammalian metabolism and correlates with many metabolic disorders, such as obesity and diabetes. Dietary restriction (DR) is, on the other hand, known to prevent the development of metabolic disorders. The current Western diets are highly enriched in fat and it is as yet unclear whether DR on a certain high-fat (HF) diet elicits similar beneficial effects on health. Here, we report that HF-DR improves metabolic health of mice, compared to mice receiving the same diet on an ad-libitum basis (HF-AL). Already after five weeks of restriction the serum levels of cholesterol and leptin were significantly decreased in HF-DR mice, while their glucose sensitivity and serum adiponectin levels were increased. The body weight and measured serum parameters remained stable in the following 7 weeks of restriction, implying metabolic adaptation. To understand the molecular events associated with this adaptation, we analysed gene expression in white adipose tissue (WAT) with whole genome microarrays. HF-DR strongly influenced gene expression in WAT; in total 8,643 genes were differentially expressed between both groups of mice, with a major role for genes involved in lipid metabolism and mitochondrial functioning. This was confirmed by qRT-PCR and substantiated by an increase in mitochondrial density in WAT of HF-DR mice. These results provide new insights in the metabolic flexibility of dietary restricted animals and suggest the development of substrate efficiency. Limiting food intake by decreasing portion sizes, while maintaining energy sufficiency, may similarly benefit metabolic health in humans.

Project description:Ageing alters cellular homeostasis thereby compromising multiple cellular processes such as transcription and splicing. However, both the extent of these changes and the molecular mechanisms are not well understood so far. In order to address this question, we analyzed transcription-coupled processes on a genomic scale in five animal species (C. elegans, D. melanogaster, M. musculus, R. norvegicus, H. sapiens) at different adult life stages. Using total RNA profiling, we quantified alterations of transcriptional elongation speed, splicing efficiency, and splicing precision. We consistently observed across all analyzed species, that the genome-average speed of RNA polymerase II (Pol-II) increased with age. These effects were reverted under lifespan-extending conditions, such as dietary restriction or modulation of insulin signaling. Reducing the speed of Pol-II in worms and flies improved splicing efficiency and increased lifespan. We further observed reduced precision in nucleosome positioning in senescent compared to proliferating cells, which correlated with reduced splicing efficiency. Thus, an age-associated increase of transcriptional speed results in reduced splicing efficiency and splicing quality. These findings substantially extend our understanding about the molecular mechanisms driving animal aging, and suggest new mechanisms underlying lifespan-extending interventions.

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