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First-Degree Relatives of Type 2 Diabetic Patients Have Reduced Expression of Genes Involved in Fatty Acid Metabolism in Skeletal Muscle.

Author:
  • Targ Elgzyri
  • Hemang Parikh
  • Yuedan Zhou
  • Marloes Dekker Nitert
  • Tina Rönn
  • A B Segerström
  • Charlotte Ling
  • Paul Franks
  • Per Wollmer
  • Karl-Fredrik Eriksson
  • Leif Groop
  • Ola Hansson
Publishing year: 2012
Language: English
Pages: 1332-1337
Publication/Series: Journal of Clinical Endocrinology and Metabolism
Volume: 97
Issue: 7
Document type: Journal article
Publisher: The Endocrine Society

Abstract english

Context:

First-degree relatives of patients with type 2 diabetes (FH+) have been shown to have decreased energy expenditure and decreased expression of mitochondrial genes in skeletal muscle. In previous studies, it has been difficult to distinguish whether mitochondrial dysfunction and differential regulation of genes are primary (genetic) or due to reduced physical activity, obesity, or other correlated factors.



Objective:

The aim of this study was to investigate whether mitochondrial dysfunction is a primary defect or results from an altered metabolic state.Design:We compared gene expression in skeletal muscle from 24 male subjects with FH and 26 without FH matched for age, glucose tolerance, VO(2peak) (peak oxygen uptake), and body mass index using microarrays. Additionally, type fiber composition, mitochondrial DNA content, and citrate synthase activity were measured. The results were followed up in an additional cohort with measurements of in vivo metabolism.



Results:

FH+vs. FH- subjects showed reduced expression of mitochondrial genes (P = 2.75 x 10(-6)), particularly genes involved in fatty acid metabolism (P = 4.08 x 10(-7)), despite similar mitochondrial DNA content. Strikingly, a 70% reduced expression of the monoamine oxidase A (MAOA) gene was found in FH+ vs. FH- individuals (P = 0.0009). Down-regulation of the genes involved in fat metabolism was associated with decreased in vivo fat oxidation and increased glucose oxidation examined in an additional cohort of elderly men.



Conclusions:

These results suggest that genetically altered fatty acid metabolism predisposes to type 2 diabetes and propose a role for catecholamine-metabolizing enzymes like MAOA in the regulation of energy metabolism.

Keywords

  • Endocrinology and Diabetes

Other

Published
  • Diabetes and Endocrinology
  • Epigenetics and Diabetes
  • Genetic and Molecular Epidemiology
  • Clinical Physiology, Malmö
  • Clinical Vascular Disease Research
  • ISSN: 1945-7197
Tina Rönn
E-mail: tina.ronn [at] med.lu.se

Assistant researcher

Epigenetics and Diabetes

+46 40 39 12 18

CRC 91-12-021

33

Lund University Diabetes Centre, CRC, SUS Malmö, Entrance 72, House 91:12. SE-205 02 Malmö. Telephone: +46 40 39 10 00