Project description:Selenium-binding protein 1 (Selenbp1) is a 2,3,7,8-tetrechlorodibenzo-p-dioxin inducible protein whose function is yet to be comprehensively elucidated. As the highly homologous isoform, Selenbp2, is expressed at low levels in the kidney, it is worthwhile to compare wild-type C57BL mice and Selenbp1-deficient mice under dioxin-free conditions. In this study, we conducted a comprehensive analysis of Selenbp1-Knockout mice to elucidate the role of Selenbp1 in the kidneys of wild-type C57BL mice under non-dioxin-administered conditions. Data from DNA microarray analysis suggested that Selenbp1 is involved in lipid metabolism. The results of real-time RT-PCR confirmed that ablation of Selenbp1 alters lipid metabolism via the Ppara pathway.

Project description:Short-term fasting elicits beneficial effects in mice and humans, including protection from chemotherapy toxicity, but the involved mechanisms are not well understood. We collected blood samples from healthy human volunteers and mice before and after 36 or 24 hours of fasting, respectively, to measure fatty acid composition of erythrocyte membranes, circulating miRNAs, and RNA expression at PBMCs. In both mice and humans, fasting affected the proportion of polyunsaturated versus saturated and monounsaturated fatty acids at the erythrocyte membrane. Also, fasting significantly reduced the expression at PBMCs of insulin signaling-related genes, including the SREBP lipid-metabolizing pathway, in correlation with changes in membrane fatty acids. We tested the relevance of these fatty acid homeostasis parameters using a complete platform to monitor chemotherapy toxicity in mice. When fasted for 24 hours before and 24 hours after administration of the chemotherapeutic drug oxaliplatin, mice showed a strong protection from kidney, liver, heart and bone marrow toxicity. Importantly, the newly discovered fasting parameters defined two clearly separated groups of individuals that accurately predicted a differential protection from chemotherapy toxicity. Our results reveal a novel mechanism of fasting associated with fatty acids homeostasis, and provide novel biomarkers of fasting to predict fasting-mediated protection from chemotherapy toxicity.

Project description:PDAC selenium ex vivo treatment

Project description:Mouse liver transcriptome under the condition of fasting, Heme induction and plasmodium infection

Project description:Methanococcus maripaludis utilizes selenocysteine-(Sec-) containing proteins (selenoproteins), mostly active in the organism’s primary energy metabolism, methanogenesis. Under selenium depletion, M. maripaludis employs a set of enzymes containing cysteine (Cys) instead of Sec. The genes coding for these Sec-/Cys-containing isoforms are the only genes known expression of which is influenced by the selenium status of the cell. Using quantitative proteomics and transcriptomics approx. 7% and 12%, respectively, of all genes/proteins were differentially expressed/synthesized in response to the selenium supply. Some of the genes identified involve methanogenesis, nitrogenase functions, and putative transporters. An increase of transcript abundance for putative transporters under selenium-depleted conditions indicated the organism’s effort to tap into alternative sources of selenium. Selenium sources M. maripaludis is known to utilize are selenite and dimethylselenide. To expand this list, a selenium responsive reporter strain was assessed with nine other, environmentally relevant selenium species. While some had a similar biological window as selenite, others were effectively utilized at lower concentrations. Conversely, selenate and seleno-amino acids were only utilized at unphysiologically high concentrations and two compounds were not utilized at all. To address the role of the selenium-regulated putative transporters in selenium transport, M. maripaludis mutant strains lacking one or two of the putative transporters were tested for the capability to utilize the different selenium species. Of the five putative transporters analyzed by loss-of-function mutagenesis, none appeared to be absolutely required for utilizing any of the selenium species tested, indicating they have redundant and/or overlapping specificities, or are not dedicated selenium transporters.

Project description:We studied the application of transcriptome technology in alfalfa selenium treatment. After spraying sodium selenite on the leaves, the process of selenium absorption and assimilation of alfalfa is unknown. The time point of transcriptome determination was determined by measuring the change of selenium content. Our results showed that 12 h was the key point of the change of selenium content in alfalfa, that is, the selenium content increased continuously before 12 h, decreased gradually after 12 h, and remained stable after 48 h. Transcriptome sequencing showed that phosphorus transporter and endocytosis related genes may be involved in selenium absorption at 12 h compared with 0 H. 12-48 h, some thiometabolic pathways may be involved in selenium metabolism and ubiquitination pathway, which may be the detoxification pathway of selenoprotein.

Project description:Moderate selenium deficiency may lead to an impaired capacity to cope with health challenges. Functional effects of suboptimal selenium intake are not fully known, and biomarkers for an insufficient selenium supply are inadequate. We therefore fed mice diets of moderately deficient or adequate selenium intake for 6 weeks. Changes in global gene expression were monitored by microarray analysis in splenic leukocytes. Genes for four selenoproteins, Sepw1, Gpx1, Selh and Sep15, were the most significantly down-regulated in moderate selenium deficiency, and this was confirmed by quantitative polymerase chain reaction (qPCR). Classification of significantly affected genes revealed that processes related to inflammation, heme biosynthesis, DNA replication and transcription, cell cycle and transport were affected by selenium restriction. Down-regulation by moderate selenium deficiency of specific genes involved in inflammation and heme biosynthesis was confirmed by qPCR. Myeloperoxidase and lysozyme activities were decreased in selenium-restricted leukocytes, providing evidence for functional consequences. Genes for 31 nuclear factor (NF)-κB targets were down-regulated in moderate selenium deficiency, indicating an impaired NF-κB signaling. Together, the observed changes point to a disturbance in inflammatory response. The selenoproteins found here to be sensitive to selenium intake in murine leukocytes might also be useful as biomarkers for a moderate selenium deficiency in humans.

Project description:Little is known about the impact of fasting on gene regulation in human adipose tissue. Accordingly, the objective of this study was to investigate the effects of fasting on adipose tissue gene expression in humans. To that end, subcutaneous adipose tissue biopsies were collected from volunteers 2h and 26h after consumption of a standardized meal. For comparison, epididymal adipose tissue was collected from C57Bl/6J mice after a 16h fast and in the ab-libitum fed state. Transcriptome analysis was carried out using Affymetrix microarrays. We found that, 1) fasting downregulated numerous metabolic pathways in human adipose tissue, including triglyceride and fatty acid synthesis, glycolysis and glycogen synthesis, TCA cycle, oxidative phosphorylation, mitochondrial translation, and insulin signaling; 2) fasting downregulated genes involved in proteasomal degradation in human adipose tissue; 3) fasting had much less pronounced effects on the adipose tissue transcriptome in humans than mi ce; 4) although major overlap in fasting-induced gene regulation was observed between human and mouse adipose tissue, many genes were differentially regulated in the two species, including genes involved in insulin signaling (PRKAG2, PFKFB3), PPAR signaling (PPARG, ACSL1, HMGCS2, SLC22A5, ACOT1), glycogen metabolism (PCK1, PYGB), and lipid droplets (PLIN1, PNPLA2, CIDEA, CIDEC). In conclusion, although numerous genes and pathways are regulated similarly by fasting in human and mouse adipose tissue, many genes show very distinct responses to fasting in humans and mice. Our data provide a useful resource to study adipose tissue function during fasting.

Project description:Little is known about the impact of fasting on gene regulation in human adipose tissue. Accordingly, the objective of this study was to investigate the effects of fasting on adipose tissue gene expression in humans. To that end, subcutaneous adipose tissue biopsies were collected from volunteers 2h and 26h after consumption of a standardized meal. For comparison, epididymal adipose tissue was collected from C57Bl/6J mice after a 16h fast and in the ab-libitum fed state. Transcriptome analysis was carried out using Affymetrix microarrays. We found that, 1) fasting downregulated numerous metabolic pathways in human adipose tissue, including triglyceride and fatty acid synthesis, glycolysis and glycogen synthesis, TCA cycle, oxidative phosphorylation, mitochondrial translation, and insulin signaling; 2) fasting downregulated genes involved in proteasomal degradation in human adipose tissue; 3) fasting had much less pronounced effects on the adipose tissue transcriptome in humans than mi ce; 4) although major overlap in fasting-induced gene regulation was observed between human and mouse adipose tissue, many genes were differentially regulated in the two species, including genes involved in insulin signaling (PRKAG2, PFKFB3), PPAR signaling (PPARG, ACSL1, HMGCS2, SLC22A5, ACOT1), glycogen metabolism (PCK1, PYGB), and lipid droplets (PLIN1, PNPLA2, CIDEA, CIDEC). In conclusion, although numerous genes and pathways are regulated similarly by fasting in human and mouse adipose tissue, many genes show very distinct responses to fasting in humans and mice. Our data provide a useful resource to study adipose tissue function during fasting.

Project description:Background; In the postabsorptive state, the portal-drained viscera are a major energy consumer, but a comprehensive overview of the adaptive fasting response in the liver is lacking. Hence, gene-expression profiling, pathway, network and gene-set enrichment analysis and immunohistochemistry were carried out on mouse liver after 0, 12, 24, and 72 hours of fasting. Results; Liver weight has fallen to 50% of control after three days of fasting, hepatocyte size was reduced with no apparent increase in apoptosis, while the basic liver structure and metabolic zonnation were preserved. Expression profiling and pathway analysis depicted four master processes, all with response peaking at 24 hours, and all but one decreasing towards 72h. Changes in gene expression were compatible with cellular energy deficiency, and metabolic adaptations were directed at enhanced glucose production, stimulation of lipid catabolism and ketone body synthesis, and strongly augmented ATP production. Consequently, the expression of genes involved in oxidative and endoplasmic reticulum stress response was increased. In addition, urea cycle genes were strongly upregulated during whole duration of fasting, in spite no obvious increase in amino-acid catabolism. Major physiological change upon continued fasting was restoration of glycogen reserves, but with reverse localization, demonstrating utilization of different glycogenic precursor compared to the fed controls. Conclusion; The changes in liver gene expression indicate a rapid onset of generating glucose and ketone bodies during short, and a return to near normal situation in prolonged fasting. The reason apparently lies in glycogen repletion, due to late fasting glucose production by (gut and) kidney. Experiment Overall Design: Male FVB mice (Charles River, Maastricht, The Netherlands) were housed at 20-22°C, 50-60% humidity, a 12 hours light/dark cycle, and food and water ad libitum. At 6 weeks of age, mice were fasted by removing chow for up to 72 hours before sacrifice (n = 6 per group). All animals were sacrificed between 9:00 and 10:00 a.m. by cervical dislocation. The liver was removed quickly, weighed, snap-frozen in liquid N2, and stored at -80°C. Total intestinal RNA was extracted from frozen tissue using TRIzol (Invitrogen), followed by a cleanup through a RNeasy column (Qiagen). The quality of RNA was assessed with the RNA 6000 Nano LabChip® Kit in an Agilent 2100 bioanalyzer (Agilent Technologies, Palo Alto, USA). The 60-mer Mouse Development (22K) Oligo Microarray G4120A (Agilent) was used. Three arrays per experimental condition were used. Per microarray, 20 μg mRNA, pooled from 2 livers, was reverse transcribed with Cy3-labelled dCTP (Perkin Elmer, Boston, USA), using the Agilent Fluorescent Direct Label Kit. Cy5-labeled cDNA produced from RNA pooled from livers of 6 fed animals served as the common reference across all arrays. Hybridized cDNAs were detected with Agilentâ??s dual-laser microarray slide scanner. The data were retrieved with Agilentâ??s Feature Extraction software 6.1.1.