Tara M Henagan1, Barbara Stefanska1, Zhide Fang2, Alexandra M Navard3, Jianping Ye4, Natalie R Lenard5, Prasad P Devarshi1. 1. Department of Nutrition Science, Purdue University, West Lafayette, IN, USA. 2. Biostatistics Program, School of Public Health, Louisiana State University Health Sciences Center, New Orleans, LA, USA. 3. Neurosignaling Laboratory, Pennington Biomedical Research Center, Baton Rouge, LA, USA. 4. Antioxidant and Gene Regulation Laboratory, Pennington Biomedical Research Center, Baton Rouge, LA, USA. 5. Department of Sciences, Our Lady of the Lake College, Baton Rouge, LA, USA.
Abstract
BACKGROUND AND PURPOSE: Sodium butyrate (NaB), an epigenetic modifier, is effective in promoting insulin sensitivity. The specific genomic loci and mechanisms underlying epigenetically induced obesity and insulin resistance and the targets of NaB are not fully understood. EXPERIMENTAL APPROACH: The anti-diabetic and anti-obesity effects of NaB treatment were measured by comparing phenotypes and physiologies of C57BL/6J mice fed a low-fat diet (LF), high-fat diet (HF) or high-fat diet plus NaB (HF + NaB) for 10 weeks. We determined a possible mechanism of NaB action through induction of beneficial skeletal muscle mitochondrial adaptations and applied microccocal nuclease digestion with sequencing (MNase-seq) to assess whole genome differences in nucleosome occupancy or positioning and to identify associated epigenetic targets of NaB. KEY RESULTS: NaB prevented HF diet-induced increases in body weight and adiposity without altering food intake or energy expenditure, improved insulin sensitivity as measured by glucose and insulin tolerance tests, and decreased respiratory exchange ratio. In skeletal muscle, NaB increased the percentage of type 1 fibres, improved acylcarnitine profiles as measured by metabolomics and produced a chromatin structure, determined by MNase-seq, similar to that seen in LF. Targeted analysis of representative nuclear-encoded mitochondrial genes showed specific repositioning of the -1 nucleosome in association with altered gene expression. CONCLUSIONS AND IMPLICATIONS: NaB treatment may be an effective pharmacological approach for type 2 diabetes and obesity by inducing -1 nucleosome repositioning within nuclear-encoded mitochondrial genes, causing skeletal muscle mitochondrial adaptations that result in more complete β-oxidation and a lean, insulin sensitive phenotype.
BACKGROUND AND PURPOSE:Sodium butyrate (NaB), an epigenetic modifier, is effective in promoting insulin sensitivity. The specific genomic loci and mechanisms underlying epigenetically induced obesity and insulin resistance and the targets of NaB are not fully understood. EXPERIMENTAL APPROACH: The anti-diabetic and anti-obesity effects of NaB treatment were measured by comparing phenotypes and physiologies of C57BL/6J mice fed a low-fat diet (LF), high-fat diet (HF) or high-fat diet plus NaB (HF + NaB) for 10 weeks. We determined a possible mechanism of NaB action through induction of beneficial skeletal muscle mitochondrial adaptations and applied microccocal nuclease digestion with sequencing (MNase-seq) to assess whole genome differences in nucleosome occupancy or positioning and to identify associated epigenetic targets of NaB. KEY RESULTS:NaB prevented HF diet-induced increases in body weight and adiposity without altering food intake or energy expenditure, improved insulin sensitivity as measured by glucose and insulin tolerance tests, and decreased respiratory exchange ratio. In skeletal muscle, NaB increased the percentage of type 1 fibres, improved acylcarnitine profiles as measured by metabolomics and produced a chromatin structure, determined by MNase-seq, similar to that seen in LF. Targeted analysis of representative nuclear-encoded mitochondrial genes showed specific repositioning of the -1 nucleosome in association with altered gene expression. CONCLUSIONS AND IMPLICATIONS: NaB treatment may be an effective pharmacological approach for type 2 diabetes and obesity by inducing -1 nucleosome repositioning within nuclear-encoded mitochondrial genes, causing skeletal muscle mitochondrial adaptations that result in more complete β-oxidation and a lean, insulin sensitive phenotype.
Authors: Adeel Safdar; Jonathan P Little; Andrew J Stokl; Bart P Hettinga; Mahmood Akhtar; Mark A Tarnopolsky Journal: J Biol Chem Date: 2011-01-18 Impact factor: 5.157
Authors: Anthony Nicholson; Peter C Reifsnyder; Rachel D Malcolm; Charlotte A Lucas; Grant R MacGregor; Weidong Zhang; Edward H Leiter Journal: Obesity (Silver Spring) Date: 2010-01-07 Impact factor: 5.002
Authors: David J Pagliarini; Sarah E Calvo; Betty Chang; Sunil A Sheth; Scott B Vafai; Shao-En Ong; Geoffrey A Walford; Canny Sugiana; Avihu Boneh; William K Chen; David E Hill; Marc Vidal; James G Evans; David R Thorburn; Steven A Carr; Vamsi K Mootha Journal: Cell Date: 2008-07-11 Impact factor: 41.582
Authors: Hua V Lin; Andrea Frassetto; Edward J Kowalik; Andrea R Nawrocki; Mofei M Lu; Jennifer R Kosinski; James A Hubert; Daphne Szeto; Xiaorui Yao; Gail Forrest; Donald J Marsh Journal: PLoS One Date: 2012-04-10 Impact factor: 3.240
Authors: Stephen P H Alexander; Helen E Benson; Elena Faccenda; Adam J Pawson; Joanna L Sharman; Michael Spedding; John A Peters; Anthony J Harmar Journal: Br J Pharmacol Date: 2013-12 Impact factor: 8.739
Authors: Linda Sommese; Alberto Zullo; Francesco Paolo Mancini; Rossella Fabbricini; Andrea Soricelli; Claudio Napoli Journal: Epigenetics Date: 2017-01-06 Impact factor: 4.528
Authors: Tao Yang; Kacy L Magee; Luis M Colon-Perez; Riley Larkin; Yan-Shin Liao; Eliza Balazic; Jonathan R Cowart; Rebeca Arocha; Ty Redler; Marcelo Febo; Thomas Vickroy; Christopher J Martyniuk; Leah R Reznikov; Jasenka Zubcevic Journal: Acta Physiol (Oxf) Date: 2019-02-20 Impact factor: 6.311