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2. Grain versus AIN: Common rodent diets differentially affect health outcomes in adult C57BL/6j mice.

Author

Schipper, Lidewij, Tims, Sebastian, Timmer, Eva, Lohr, Julia, Rakhshandehroo, Maryam, and Harvey, Louise

Subjects
LABORATORY mice, DIET, LONGEVITY, BODY composition, BODY weight, FISH feeds, GRAIN
Abstract

Semi-synthetic and grain-based diets are common rodent diets for biomedical research. Both diet types are considered nutritionally adequate to support breeding, growth, and long life, yet there are fundamental differences between them that may affect metabolic processes. We have characterized the effects of diet type on breeding outcomes, metabolic phenotype, and microbiota profile in adult mice. Healthy 8-week-old female and male C57BL/6J mice were fed a semi-synthetic or a grain-based diet for 12 weeks and changes in body weight and body composition were monitored. Breeding outcomes were determined. Body fat accumulation of female mice was lower on the semi-synthetic diet than on the grain-based diet. Pregnancy rate and newborn pup survival appeared to be lower in mice exposed to semi-synthetic diet compared to grain-based diet. Both female and male mice showed a profound change in fecal microbiota alpha and beta diversity depending on diet type. Our study shows that type of rodent diet may affect breeding outcomes whilst influencing metabolism and health of female laboratory mice. These factors have the potential to influence other experimental outcomes and the results suggest that semi-synthetic and grain-based diets are not interchangeable in research using rodent models. Careful consideration and increased understanding of the consequences of diet choice would lead to improvements in experimental design and reproducibility of study results. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Health relevance of lowering postprandial glycaemia in the paediatric population through diet’ : results from a multistakeholder workshop

Author

Vinoy, Sophie, Goletzke, Janina, Rakhshandehroo, Maryam, Schweitzer, Lisa, Flourakis, Matthieu, Körner, Antje, Alexy, Ute, van Schothorst, Evert M., Ceriello, Antonio, Zakrzewski-Fruer, Julia K., Buyken, Anette, Vinoy, Sophie, Goletzke, Janina, Rakhshandehroo, Maryam, Schweitzer, Lisa, Flourakis, Matthieu, Körner, Antje, Alexy, Ute, van Schothorst, Evert M., Ceriello, Antonio, Zakrzewski-Fruer, Julia K., and Buyken, Anette

Abstract

To summarize current knowledge and gaps regarding the role of postprandial glycaemic response in the paediatric population, a workshop was organized in June 2021 by the European branch of the International Life Science Institute (ILSI). This virtual event comprised of talks given by experts followed by in-depth discussions in breakout sessions with workshop participants. The main pre-specified topics addressed by the workshop organizing committee to the invited speakers and the workshop participants were: (1) the role of glycaemic responses for paediatric health, based on mechanistic insights from animal and human data, and long-term evidence from observational and intervention studies in paediatric populations, and (2) changes in metabolism and changes in dietary needs from infancy to adolescence. Each talk as well as the discussions were summarised, including the main identified research gaps. The workshop led to the consensus on the crucial role on health of postprandial glycaemic response in paediatric population. However, a lack of scientific data has been identified regarding detailed glucose and insulin profiles in response to foods commonly consumed by paediatric populations, as well as a lack of long-term evidence including the need for suitable predictors during childhood and adolescence to anticipate health effects during adulthood.

Published
2023

5. Natural killer T cells in adipose tissue prevent insulin resistance

Author

Schipper, Henk S., Rakhshandehroo, Maryam, van de Graaf, Stan F.J., Venken, Koen, Koppen, Arjen, Stienstra, Rinke, Prop, Serge, Meerding, Jenny, Hamers, Nicole, Besra, Gurdyal, Boon, Louis, Nieuwenhuis, Edward E.S., Elewaut, Dirk, Prakken, Berent, Kersten, Sander, Boes, Marianne, and Kalkhoven, Eric

Subjects
Prevention, Physiological aspects, Risk factors, Killer cells -- Physiological aspects, Insulin resistance -- Risk factors -- Prevention, Adipose tissue -- Physiological aspects, T cells -- Physiological aspects, Adipose tissues -- Physiological aspects
Abstract

Introduction More than one-third of the U.S. population has insulin resistance, a condition that is predominantly caused by obesity and is associated with adipocyte dysfunction together with chronic low-grade adipose [...], Lipid overload and adipocyte dysfunction are key to the development of insulin resistance and can be induced by a high-fat diet. CD1d-restricted invariant natural killer T (iNKT) cells have been proposed as mediators between lipid overload and insulin resistance, but recent studies found decreased iNKT cell numbers and marginal effects of iNKT cell depletion on insulin resistance under high-fat diet conditions. Here, we focused on the role of iNKT cells under normal conditions. We showed that iNKT cell-deficient mice on a low-fat diet, considered a normal diet for mice, displayed a distinctive insulin resistance phenotype without overt adipose tissue inflammation. Insulin resistance was characterized by adipocyte dysfunction, including adipocyte hypertrophy, increased leptin, and decreased adiponectin levels. The lack of liver abnormalities in CD1d-null mice together with the enrichment of CD1d-restricted iNKT cells in both mouse and human adipose tissue indicated a specific role for adipose tissue-resident iNKT cells in the development of insulin resistance. Strikingly, iNKT cell function was directly modulated by adipocytes, which acted as lipid antigen-presenting cells in a CD1d-mediated fashion. Based on these findings, we propose that, especially under low-fat diet conditions, adipose tissue-resident iNKT cells maintain healthy adipose tissue through direct interplay with adipocytes and prevent insulin resistance.

Published
2012
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6. Adipocytes harbor a glucosylceramide biosynthesis pathway involved in iNKT cell activation

Author

Rakhshandehroo, Maryam, van Eijkeren, Robert J., Gabriel, Tanit L., de Haar, Colin, Gijzel, Sanne M.W., Hamers, Nicole, Ferraz, Maria J., Aerts, Johannes M.F.G., Schipper, Henk S., van Eijk, Marco, Boes, Marianne, Kalkhoven, Eric, Rakhshandehroo, Maryam, van Eijkeren, Robert J., Gabriel, Tanit L., de Haar, Colin, Gijzel, Sanne M.W., Hamers, Nicole, Ferraz, Maria J., Aerts, Johannes M.F.G., Schipper, Henk S., van Eijk, Marco, Boes, Marianne, and Kalkhoven, Eric

Published
2019

7. Adipocytes harbor a glucosylceramide biosynthesis pathway involved in iNKT cell activation

Author

CMM Groep Kalkhoven, Circulatory Health, CDL Immunoserologie, UMC Utrecht, Apotheek Celtherapie Faciliteit, Infection & Immunity, Cardiologie patientenzorg, Child Health, CTI Boes, Immuno/reuma onderzoek 2 (Boes), Onderzoek, CMM Sectie Molecular Cancer Research, Staf Onderwijs en Opleidingen, Cancer, Rakhshandehroo, Maryam, van Eijkeren, Robert J., Gabriel, Tanit L., de Haar, Colin, Gijzel, Sanne M.W., Hamers, Nicole, Ferraz, Maria J., Aerts, Johannes M.F.G., Schipper, Henk S., van Eijk, Marco, Boes, Marianne, Kalkhoven, Eric, CMM Groep Kalkhoven, Circulatory Health, CDL Immunoserologie, UMC Utrecht, Apotheek Celtherapie Faciliteit, Infection & Immunity, Cardiologie patientenzorg, Child Health, CTI Boes, Immuno/reuma onderzoek 2 (Boes), Onderzoek, CMM Sectie Molecular Cancer Research, Staf Onderwijs en Opleidingen, Cancer, Rakhshandehroo, Maryam, van Eijkeren, Robert J., Gabriel, Tanit L., de Haar, Colin, Gijzel, Sanne M.W., Hamers, Nicole, Ferraz, Maria J., Aerts, Johannes M.F.G., Schipper, Henk S., van Eijk, Marco, Boes, Marianne, and Kalkhoven, Eric

Published
2019

11. CD1d-restricted NKT cell function prevents insulin resistance in lean mice, and is regulated by adipocytes and is regulated by adipocytes

Author

Schipper, Henk S., Rakhshandehroo, Maryam, van de Graaf, Stan F., Venken, Koen, Koppen, Arjen, Stienstra, Rinke, Prop, Serge, Meerding, Jenny, Hamers, Nicole, Besra, Gurdyal, Boon, Louis, Nieuwenhuis, Edward E., Elewaut, Dirk, Prakken, Berent, Kersten, Sander, Boes, Marianne, Kalkhoven, Eric, Schipper, Henk S., Rakhshandehroo, Maryam, van de Graaf, Stan F., Venken, Koen, Koppen, Arjen, Stienstra, Rinke, Prop, Serge, Meerding, Jenny, Hamers, Nicole, Besra, Gurdyal, Boon, Louis, Nieuwenhuis, Edward E., Elewaut, Dirk, Prakken, Berent, Kersten, Sander, Boes, Marianne, and Kalkhoven, Eric

Abstract

Lipid overload and adipocyte dysfunction are key to the development of insulin resistance and can be induced by a high-fat diet. CD1d-restricted invariant natural killer T (iNKT) cells have been proposed as mediators between lipid overload and insulin resistance, but recent studies found decreased iNKT cell numbers and marginal effects of iNKT cell depletion on insulin resistance under high-fat diet conditions. Here, we focused on the role of iNKT cells under normal conditions. We showed that iNKT cell–deficient mice on a low-fat diet, considered a normal diet for mice, displayed a distinctive insulin resistance phenotype without overt adipose tissue inflammation. Insulin resistance was characterized by adipocyte dysfunction, including adipocyte hypertrophy, increased leptin, and decreased adiponectin levels. The lack of liver abnormalities in CD1d-null mice together with the enrichment of CD1d-restricted iNKT cells in both mouse and human adipose tissue indicated a specific role for adipose tissue–resident iNKT cells in the development of insulin resistance. Strikingly, iNKT cell function was directly modulated by adipocytes, which acted as lipid antigen-presenting cells in a CD1d-mediated fashion. Based on these findings, we propose that, especially under low-fat diet conditions, adipose tissue–resident iNKT cells maintain healthy adipose tissue through direct interplay with adipocytes and prevent insulin resistance., Lipid overload and adipocyte dysfunction are key to the development of insulin resistance and can be induced by a high-fat diet. CD1d-restricted invariant natural killer T (iNKT) cells have been proposed as mediators between lipid overload and insulin resistance, but recent studies found decreased iNKT cell numbers and marginal effects of iNKT cell depletion on insulin resistance under high-fat diet conditions. Here, we focused on the role of iNKT cells under normal conditions. We showed that iNKT cell–deficient mice on a low-fat diet, considered a normal diet for mice, displayed a distinctive insulin resistance phenotype without overt adipose tissue inflammation. Insulin resistance was characterized by adipocyte dysfunction, including adipocyte hypertrophy, increased leptin, and decreased adiponectin levels. The lack of liver abnormalities in CD1d-null mice together with the enrichment of CD1d-restricted iNKT cells in both mouse and human adipose tissue indicated a specific role for adipose tissue–resident iNKT cells in the development of insulin resistance. Strikingly, iNKT cell function was directly modulated by adipocytes, which acted as lipid antigen-presenting cells in a CD1d-mediated fashion. Based on these findings, we propose that, especially under low-fat diet conditions, adipose tissue–resident iNKT cells maintain healthy adipose tissue through direct interplay with adipocytes and prevent insulin resistance.

Published
2012

12. Peroxisome proliferator-activated receptor alpha target genes

Author

Rakhshandehroo, Maryam, Knoch, Bianca, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Knoch, Bianca, Muller, Michael, and Kersten, Sander

Abstract

The peroxisome proliferator-activated receptor alpha (PPARα) is a ligand-activated transcription factor involved in the regulation of a variety of processes, ranging from inflammation and immunity to nutrientmetabolism and energy homeostasis. PPARα serves as amolecular target for hypolipidemic fibrates drugs which bind the receptor with high affinity. Furthermore, PPARα binds and is activated by numerous fatty acids and fatty acid-derived compounds. PPARα governs biological processes by altering the expression of a large number of target genes. Accordingly, the specific role of PPARα is directly related to the biological function of its target genes. Here, we present an overview of the involvement of PPARα in lipid metabolism and other pathways through a detailed analysis of the different known or putative PPARα target genes. The emphasis is on gene regulation by PPARα in liver although many of the results likely apply to other organs and tissues as well.

Published
2010

13. Comparative analysis of gene regulation by the transcription factor PPARα between mouse and human

Author

Rakhshandehroo, Maryam, Hooiveld, Guido, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Hooiveld, Guido, Muller, Michael, and Kersten, Sander

Abstract

Studies in mice have shown that PPARα is an important regulator of hepatic lipid metabolism and the acute phase response. However, little information is available on the role of PPARα in human liver. Here we set out to compare the function of PPARα in mouse and human hepatocytes via analysis of target gene regulation. Primary hepatocytes from 6 human and 6 mouse donors were treated with PPARα agonist Wy14643 and gene expression profiling was performed using Affymetrix GeneChips followed by a systems biology analysis. Baseline PPARα expression was similar in human and mouse hepatocytes. Depending on species and time of exposure, Wy14643 significantly induced the expression of 362-672 genes. Surprisingly minor overlap was observed between the Wy14643-regulated genes from mouse and human, although more substantial overlap was observed at the pathway level. Xenobiotics metabolism and apolipoprotein synthesis were specifically regulated by PPARα in human hepatocytes, whereas glycolysis-gluconeogenesis was regulated specifically in mouse hepatocytes. Most of the genes commonly regulated in mouse and human were involved in lipid metabolism and many represented known PPARα targets, including CPT1A, HMGCS2, FABP, ACSL, and ADFP. Several genes were identified that were specifically induced by PPARα in human (MBL2, ALAS1, CYP1A1, TSKU) or mouse (Fbp2, lgals4, Cd36, Ucp2, Pxmp4). Furthermore, several putative novel PPARα targets were identified that were commonly regulated in both species, including CREB3L3, KLF10, KLF11 and MAP3K8. Our results suggest that PPARα activation has a major impact on gene regulation in human hepatocytes. Importantly, the role of PPARα as master regulator of hepatic lipid metabolism is generally well-conserved between mouse and human. Overall, however, PPARα regulates a mostly divergent set of genes in mouse and human hepatocytes.

Published
2009

14. Comparative analysis of gene regulation by the transcription factor PPARα_mouse

Author

Rakhshandehroo, Maryam, Hooiveld, Guido, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Hooiveld, Guido, Muller, Michael, and Kersten, Sander

Abstract

Studies in mice have shown that PPARα is an important regulator of hepatic lipid metabolism and the acute phase response. However, little information is available on the role of PPARα in human liver. Here we set out to compare the function of PPARα in mouse and human hepatocytes via analysis of target gene regulation. Primary hepatocytes from 6 human and 6 mouse donors were treated with PPARα agonist Wy14643 and gene expression profiling was performed using Affymetrix GeneChips followed by a systems biology analysis. Baseline PPARα expression was similar in human and mouse hepatocytes. Depending on species and time of exposure, Wy14643 significantly induced the expression of 362-672 genes. Surprisingly minor overlap was observed between the Wy14643-regulated genes from mouse and human, although more substantial overlap was observed at the pathway level. Xenobiotics metabolism and apolipoprotein synthesis were specifically regulated by PPARα in human hepatocytes, whereas glycolysis-gluconeogenesis was regulated specifically in mouse hepatocytes. Most of the genes commonly regulated in mouse and human were involved in lipid metabolism and many represented known PPARα targets, including CPT1A, HMGCS2, FABP, ACSL, and ADFP. Several genes were identified that were specifically induced by PPARα in human (MBL2, ALAS1, CYP1A1, TSKU) or mouse (Fbp2, lgals4, Cd36, Ucp2, Pxmp4). Furthermore, several putative novel PPARα targets were identified that were commonly regulated in both species, including CREB3L3, KLF10, KLF11 and MAP3K8. Our results suggest that PPARα activation has a major impact on gene regulation in human hepatocytes. Importantly, the role of PPARα as master regulator of hepatic lipid metabolism is generally well-conserved between mouse and human. Overall, however, PPARα regulates a mostly divergent set of genes in mouse and human hepatocytes.

Published
2009

15. Early adipogenesis is regulated through USP7-mediated deubiquitination of the histone acetyltransferase TIP60

Author

Gao, Yuan, primary, Koppen, Arjen, additional, Rakhshandehroo, Maryam, additional, Tasdelen, Ismayil, additional, van de Graaf, Stan F., additional, van Loosdregt, Jorg, additional, van Beekum, Olivier, additional, Hamers, Nicole, additional, van Leenen, Dik, additional, Berkers, Celia R., additional, Berger, Ruud, additional, Holstege, Frank C.P., additional, Coffer, Paul J., additional, Brenkman, Arjan B., additional, Ovaa, Huib, additional, and Kalkhoven, Eric, additional

Published
2013
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16. Comprehensive analysis of PPARα-dependent regulation of hepatic lipid metabolism by expression profiling - 4

Author

Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, and Kersten, Sander

Abstract

PPARα is a ligand-activated transcription factor involved in the regulation of nutrient metabolism and inflammation. Although much is already known about the function of PPARα in hepatic lipid metabolism, many PPARα-dependent pathways and genes have yet to be discovered. In order to obtain an overview of PPARα-regulated genes relevant to lipid metabolism, and to probe for novel candidate PPARα target genes, livers from several animal studies in which PPARα was activated and/or disabled were analyzed by Affymetrix GeneChips. Numerous novel PPARα-regulated genes relevant to lipid metabolism were identified. Out of this set of genes, eight genes were singled out for study of PPARα-dependent regulation in mouse liver and in mouse, rat, and human primary hepatocytes, including thioredoxin interacting protein (Txnip), electron-transferring-flavoprotein β polypeptide (Etfb), electron-transferring-flavoprotein dehydrogenase (Etfdh), phosphatidylcholine transfer protein (Pctp), endothelial lipase (EL, Lipg), adipose triglyceride lipase (Pnpla2), hormone-sensitive lipase (Lipe), and monoglyceride lipase (Mgll). Using an in silico screening approach, one or more PPAR response elements (PPREs) were identified in each of these genes. Since Pnpla2, Lipe, and Mgll contribute to hepatic triglyceride hydrolysis, gene regulation was studied under conditions of elevated hepatic lipids. In wild-type mice fed a high fat diet, the decrease in hepatic lipids following treatment with the PPARα agonist Wy14643 was paralleled by significant up-regulation of Pnpla2, Lipe, and Mgll, suggesting that induction of triglyceride hydrolysis may contribute to the anti-steatotic role of PPARα. Our study illustrates the power of transcriptional profiling to uncover novel PPARα-regulated genes and pathways in liver.

Published
2007

17. Comprehensive analysis of PPARα-dependent regulation of hepatic lipid metabolism by expression profiling - 1

Author

Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, and Kersten, Sander

Abstract

PPARα is a ligand-activated transcription factor involved in the regulation of nutrient metabolism and inflammation. Although much is already known about the function of PPARα in hepatic lipid metabolism, many PPARα-dependent pathways and genes have yet to be discovered. In order to obtain an overview of PPARα-regulated genes relevant to lipid metabolism, and to probe for novel candidate PPARα target genes, livers from several animal studies in which PPARα was activated and/or disabled were analyzed by Affymetrix GeneChips. Numerous novel PPARα-regulated genes relevant to lipid metabolism were identified. Out of this set of genes, eight genes were singled out for study of PPARα-dependent regulation in mouse liver and in mouse, rat, and human primary hepatocytes, including thioredoxin interacting protein (Txnip), electron-transferring-flavoprotein β polypeptide (Etfb), electron-transferring-flavoprotein dehydrogenase (Etfdh), phosphatidylcholine transfer protein (Pctp), endothelial lipase (EL, Lipg), adipose triglyceride lipase (Pnpla2), hormone-sensitive lipase (Lipe), and monoglyceride lipase (Mgll). Using an in silico screening approach, one or more PPAR response elements (PPREs) were identified in each of these genes. Since Pnpla2, Lipe, and Mgll contribute to hepatic triglyceride hydrolysis, gene regulation was studied under conditions of elevated hepatic lipids. In wild-type mice fed a high fat diet, the decrease in hepatic lipids following treatment with the PPARα agonist Wy14643 was paralleled by significant up-regulation of Pnpla2, Lipe, and Mgll, suggesting that induction of triglyceride hydrolysis may contribute to the anti-steatotic role of PPARα. Our study illustrates the power of transcriptional profiling to uncover novel PPARα-regulated genes and pathways in liver.

Published
2007

18. Comprehensive analysis of PPARα-dependent regulation of hepatic lipid metabolism by expression profiling - 3

Author

Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, and Kersten, Sander

Abstract

PPARα is a ligand-activated transcription factor involved in the regulation of nutrient metabolism and inflammation. Although much is already known about the function of PPARα in hepatic lipid metabolism, many PPARα-dependent pathways and genes have yet to be discovered. In order to obtain an overview of PPARα-regulated genes relevant to lipid metabolism, and to probe for novel candidate PPARα target genes, livers from several animal studies in which PPARα was activated and/or disabled were analyzed by Affymetrix GeneChips. Numerous novel PPARα-regulated genes relevant to lipid metabolism were identified. Out of this set of genes, eight genes were singled out for study of PPARα-dependent regulation in mouse liver and in mouse, rat, and human primary hepatocytes, including thioredoxin interacting protein (Txnip), electron-transferring-flavoprotein β polypeptide (Etfb), electron-transferring-flavoprotein dehydrogenase (Etfdh), phosphatidylcholine transfer protein (Pctp), endothelial lipase (EL, Lipg), adipose triglyceride lipase (Pnpla2), hormone-sensitive lipase (Lipe), and monoglyceride lipase (Mgll). Using an in silico screening approach, one or more PPAR response elements (PPREs) were identified in each of these genes. Since Pnpla2, Lipe, and Mgll contribute to hepatic triglyceride hydrolysis, gene regulation was studied under conditions of elevated hepatic lipids. In wild-type mice fed a high fat diet, the decrease in hepatic lipids following treatment with the PPARα agonist Wy14643 was paralleled by significant up-regulation of Pnpla2, Lipe, and Mgll, suggesting that induction of triglyceride hydrolysis may contribute to the anti-steatotic role of PPARα. Our study illustrates the power of transcriptional profiling to uncover novel PPARα-regulated genes and pathways in liver.

Published
2007

19. Comprehensive analysis of PPARα-dependent regulation of hepatic lipid metabolism by expression profiling - 5

Author

Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, and Kersten, Sander

Abstract

PPARα is a ligand-activated transcription factor involved in the regulation of nutrient metabolism and inflammation. Although much is already known about the function of PPARα in hepatic lipid metabolism, many PPARα-dependent pathways and genes have yet to be discovered. In order to obtain an overview of PPARα-regulated genes relevant to lipid metabolism, and to probe for novel candidate PPARα target genes, livers from several animal studies in which PPARα was activated and/or disabled were analyzed by Affymetrix GeneChips. Numerous novel PPARα-regulated genes relevant to lipid metabolism were identified. Out of this set of genes, eight genes were singled out for study of PPARα-dependent regulation in mouse liver and in mouse, rat, and human primary hepatocytes, including thioredoxin interacting protein (Txnip), electron-transferring-flavoprotein β polypeptide (Etfb), electron-transferring-flavoprotein dehydrogenase (Etfdh), phosphatidylcholine transfer protein (Pctp), endothelial lipase (EL, Lipg), adipose triglyceride lipase (Pnpla2), hormone-sensitive lipase (Lipe), and monoglyceride lipase (Mgll). Using an in silico screening approach, one or more PPAR response elements (PPREs) were identified in each of these genes. Since Pnpla2, Lipe, and Mgll contribute to hepatic triglyceride hydrolysis, gene regulation was studied under conditions of elevated hepatic lipids. In wild-type mice fed a high fat diet, the decrease in hepatic lipids following treatment with the PPARα agonist Wy14643 was paralleled by significant up-regulation of Pnpla2, Lipe, and Mgll, suggesting that induction of triglyceride hydrolysis may contribute to the anti-steatotic role of PPARα. Our study illustrates the power of transcriptional profiling to uncover novel PPARα-regulated genes and pathways in liver.

Published
2007

20. Comprehensive analysis of PPARα-dependent regulation of hepatic lipid metabolism by expression profiling - 2

Author

Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, Groot, Philip, de, Muller, Michael, and Kersten, Sander

Abstract

PPARα is a ligand-activated transcription factor involved in the regulation of nutrient metabolism and inflammation. Although much is already known about the function of PPARα in hepatic lipid metabolism, many PPARα-dependent pathways and genes have yet to be discovered. In order to obtain an overview of PPARα-regulated genes relevant to lipid metabolism, and to probe for novel candidate PPARα target genes, livers from several animal studies in which PPARα was activated and/or disabled were analyzed by Affymetrix GeneChips. Numerous novel PPARα-regulated genes relevant to lipid metabolism were identified. Out of this set of genes, eight genes were singled out for study of PPARα-dependent regulation in mouse liver and in mouse, rat, and human primary hepatocytes, including thioredoxin interacting protein (Txnip), electron-transferring-flavoprotein β polypeptide (Etfb), electron-transferring-flavoprotein dehydrogenase (Etfdh), phosphatidylcholine transfer protein (Pctp), endothelial lipase (EL, Lipg), adipose triglyceride lipase (Pnpla2), hormone-sensitive lipase (Lipe), and monoglyceride lipase (Mgll). Using an in silico screening approach, one or more PPAR response elements (PPREs) were identified in each of these genes. Since Pnpla2, Lipe, and Mgll contribute to hepatic triglyceride hydrolysis, gene regulation was studied under conditions of elevated hepatic lipids. In wild-type mice fed a high fat diet, the decrease in hepatic lipids following treatment with the PPARα agonist Wy14643 was paralleled by significant up-regulation of Pnpla2, Lipe, and Mgll, suggesting that induction of triglyceride hydrolysis may contribute to the anti-steatotic role of PPARα. Our study illustrates the power of transcriptional profiling to uncover novel PPARα-regulated genes and pathways in liver.

Published
2007

21. Comprehensive analysis of PPARa-dependent regulation of hepatic lipid metabolism by expression profiling

Author

Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, de Groot, Philip, Muller, Michael, Kersten, Sander, Rakhshandehroo, Maryam, Sanderson-Kjellberg, L.M., Matilainen, Merja, Stienstra, Rinke, Carlberg, Carsten, de Groot, Philip, Muller, Michael, and Kersten, Sander

Abstract

PPARalpha is a ligand-activated transcription factor involved in the regulation of nutrient metabolism and inflammation. Although much is already known about the function of PPARalpha in hepatic lipid metabolism, many PPARalpha-dependent pathways and genes have yet to be discovered. In order to obtain an overview of PPARalpha-regulated genes relevant to lipid metabolism, and to probe for novel candidate PPARalpha target genes, livers from several animal studies in which PPARalpha was activated and/or disabled were analyzed by Affymetrix GeneChips. Numerous novel PPARalpha-regulated genes relevant to lipid metabolism were identified. Out of this set of genes, eight genes were singled out for study of PPARalpha-dependent regulation in mouse liver and in mouse, rat, and human primary hepatocytes, including thioredoxin interacting protein (Txnip), electron-transferring-flavoprotein beta polypeptide (Etfb), electron-transferring-flavoprotein dehydrogenase (Etfdh), phosphatidylcholine transfer protein (Pctp), endothelial lipase (EL, Lipg), adipose triglyceride lipase (Pnpla2), hormone-sensitive lipase (HSL, Lipe), and monoglyceride lipase (Mgll). Using an in silico screening approach, one or more PPAR response elements (PPREs) were identified in each of these genes. Regulation of Pnpla2, Lipe, and Mgll, which are involved in triglyceride hydrolysis, was studied under conditions of elevated hepatic lipids. In wild-type mice fed a high fat diet, the decrease in hepatic lipids following treatment with the PPARalpha agonist Wy14643 was paralleled by significant up-regulation of Pnpla2, Lipe, and Mgll, suggesting that induction of triglyceride hydrolysis may contribute to the anti-steatotic role of PPARalpha. Our study illustrates the power of transcriptional profiling to uncover novel PPARalpha-regulated genes and pathways in liver., PPARalpha is a ligand-activated transcription factor involved in the regulation of nutrient metabolism and inflammation. Although much is already known about the function of PPARalpha in hepatic lipid metabolism, many PPARalpha-dependent pathways and genes have yet to be discovered. In order to obtain an overview of PPARalpha-regulated genes relevant to lipid metabolism, and to probe for novel candidate PPARalpha target genes, livers from several animal studies in which PPARalpha was activated and/or disabled were analyzed by Affymetrix GeneChips. Numerous novel PPARalpha-regulated genes relevant to lipid metabolism were identified. Out of this set of genes, eight genes were singled out for study of PPARalpha-dependent regulation in mouse liver and in mouse, rat, and human primary hepatocytes, including thioredoxin interacting protein (Txnip), electron-transferring-flavoprotein beta polypeptide (Etfb), electron-transferring-flavoprotein dehydrogenase (Etfdh), phosphatidylcholine transfer protein (Pctp), endothelial lipase (EL, Lipg), adipose triglyceride lipase (Pnpla2), hormone-sensitive lipase (HSL, Lipe), and monoglyceride lipase (Mgll). Using an in silico screening approach, one or more PPAR response elements (PPREs) were identified in each of these genes. Regulation of Pnpla2, Lipe, and Mgll, which are involved in triglyceride hydrolysis, was studied under conditions of elevated hepatic lipids. In wild-type mice fed a high fat diet, the decrease in hepatic lipids following treatment with the PPARalpha agonist Wy14643 was paralleled by significant up-regulation of Pnpla2, Lipe, and Mgll, suggesting that induction of triglyceride hydrolysis may contribute to the anti-steatotic role of PPARalpha. Our study illustrates the power of transcriptional profiling to uncover novel PPARalpha-regulated genes and pathways in liver.

Published
2007

26. Allele Compensation in Tip60+/− Mice Rescues White Adipose Tissue Function In Vivo.

Author

Gao, Yuan, Hamers, Nicole, Rakhshandehroo, Maryam, Berger, Ruud, Lough, John, and Kalkhoven, Eric

Subjects
ALLELES, HISTONE acetyltransferase, WHITE adipose tissue, TRANSCRIPTION factors, ACETYLTRANSFERASES, LABORATORY mice, ENERGY metabolism
Abstract

Adipose tissue is a key regulator of energy homestasis. The amount of adipose tissue is largely determined by adipocyte differentiation (adipogenesis), a process that is regulated by the concerted actions of multiple transcription factors and cofactors. Based on in vitro studies in murine 3T3-L1 preadipocytes and human primary preadipocytes, the transcriptional cofactor and acetyltransferase Tip60 was recently identified as an essential adipogenic factor. We therefore investigated the role of Tip60 on adipocyte differentiation and function, and possible consequences on energy homeostasis, in vivo. Because homozygous inactivation results in early embryonic lethality, Tip60+/− mice were used. Heterozygous inactivation of Tip60 had no effect on body weight, despite slightly higher food intake by Tip60+/− mice. No major effects of heterozygous inactivation of Tip60 were observed on adipose tissue and liver, and Tip60+/− displayed normal glucose tolerance, both on a low fat and a high fat diet. While Tip60 mRNA was reduced to 50% in adipose tissue, the protein levels were unaltered, suggesting compensation by the intact allele. These findings indicate that the in vivo role of Tip60 in adipocyte differentiation and function cannot be properly addressed in Tip60+/− mice, but requires the generation of adipose tissue-specific knock out animals or specific knock-in mice. [ABSTRACT FROM AUTHOR]

Published
2014
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27. Allele Compensation in Tip60+/− Mice Rescues White Adipose Tissue Function In Vivo.

Author

Gao, Yuan, Hamers, Nicole, Rakhshandehroo, Maryam, Berger, Ruud, Lough, John, and Kalkhoven, Eric

Subjects
*ALLELES, *HISTONE acetyltransferase, *WHITE adipose tissue, *TRANSCRIPTION factors, *ACETYLTRANSFERASES, *LABORATORY mice, *ENERGY metabolism
Abstract

Adipose tissue is a key regulator of energy homestasis. The amount of adipose tissue is largely determined by adipocyte differentiation (adipogenesis), a process that is regulated by the concerted actions of multiple transcription factors and cofactors. Based on in vitro studies in murine 3T3-L1 preadipocytes and human primary preadipocytes, the transcriptional cofactor and acetyltransferase Tip60 was recently identified as an essential adipogenic factor. We therefore investigated the role of Tip60 on adipocyte differentiation and function, and possible consequences on energy homeostasis, in vivo. Because homozygous inactivation results in early embryonic lethality, Tip60+/− mice were used. Heterozygous inactivation of Tip60 had no effect on body weight, despite slightly higher food intake by Tip60+/− mice. No major effects of heterozygous inactivation of Tip60 were observed on adipose tissue and liver, and Tip60+/− displayed normal glucose tolerance, both on a low fat and a high fat diet. While Tip60 mRNA was reduced to 50% in adipose tissue, the protein levels were unaltered, suggesting compensation by the intact allele. These findings indicate that the in vivo role of Tip60 in adipocyte differentiation and function cannot be properly addressed in Tip60+/− mice, but requires the generation of adipose tissue-specific knock out animals or specific knock-in mice. [ABSTRACT FROM AUTHOR]

Published
2014
Full Text
View/download PDF

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