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09 April 2018

Gene that contributes to female body shape may increase risk of type 2 diabetes by altering the development of fat cells

Scientists at King’s College London have identified a gene that in women is linked to the creation and location of new fat cells and therefore is thought to contribute to the risk of type 2 diabetes.

Adipose cell on microscope - Stock image
Adipose cell on microscope - Stock image

Published in Nature Genetics, the paper examined the effect of a gene called KLF14. The researchers found that genetic variations that control KLF14 were associated with where in the body excess fat was stored. In women, versions of the gene that result in fat being stored around the hips, rather than the abdomen, were linked to a lower risk of diabetes. 

The gene does not have an effect on overall weight but different variations of KLF14 were also related to the development and size of fat cells. Women with variations of the gene linked to the deposit of fat around the abdomen had fewer, larger fat cells which are less efficient. This means that the body’s sensitivity to insulin is decreased and therefore suggests that carriers of this variation of the gene are more at risk of diabetes.

These findings provide one of the most complete understandings of a piece of genetic data

Dr Kerrin Small, Lead Author, Department of Twin Research and Genetic Epidemiology

The study, which was an international collaboration with the University of Oxford, MRC Harwell, University of California in Los Angeles, University of Pennsylvania and others, also showed that the effects of these gene variations were specific to females. This variant of the KLF14 gene is thought to be one of the strongest known genetic risk factors for type 2 diabetes in females. Only the version of the gene inherited from an individual’s mother is active – the father’s version is silent. Women who inherited the risk version of the gene from their mother had around a 30 per cent higher risk of diabetes than those without the risk version of the gene. 

The researchers undertook analysis of biopsy and blood samples taken from 856 female participants from the TwinsUK cohort alongside fat biopsies from the Oxford BioBank and genetic data from the UK Biobank. The team also confirmed some of the findings in mouse models of the KLF14 variant although these models did not show the same female specific effects shown in human cell models.

The findings provide new insight in to a large genetic network involved in the mechanism of diabetes risk. It is hoped that this understanding may lead to better preventative measures and improved health advice in the future

Dr Kerrin Small, lead author of the study from the Department of Twin Research and Genetic Epidemiology said: ‘These findings provide one of the most complete understandings of a piece of genetic data – we have studied the type 2 diabetes associated version of the KLF14 gene to the point that we understand not only where and how it acts in the body but also who it acts in – women who inherit the diabetes associated version of the gene from their mother. 

‘We hope that by building on these findings with further research to try and understand why the gene variant only affects diabetes risk in women that we can contribute towards better treatment plans and prevention and move towards more personalised approaches to medicine.’ 

Professor Mark McCarthy, another lead author, from the University of Oxford said: ‘Being over-weight is known to increase the risk of type 2 diabetes, but this study shows that not all fat is equal: where any excess fat is stored in the body has a big impact on disease risk. Here we identify a key gene involved in women in determining whether excess fat is stored around the hips (where it tends to be free of metabolic consequences) or around the waist (where it is particularly likely to increase diabetes risk). 

Rather that assuming that genetic variations exert their effects in the same way in different people, our new work highlights the importance of taking a ‘holistic’ approach to understanding the causes of disease, interrogating how genes function in different tissues and in different sexes.’

 

For further information please contact Hannah Pluthero, Press Officer at King's College London on hannah.pluthero@kcl.ac.uk or 0207 848 3202

For further information about King's, please visit the  King's in Brief web pages