Metabolic MAGIC
Researchers have identified 38 new genetic regions that are associated with glucose and insulin levels in the blood. This brings the total number of genetic regions associated with glucose and insulin levels to 53, over half of which are associated with type 2 diabetes.
The researchers used a technology that is 100 times more powerful than previous techniques used to follow-up on genome-wide association results. This technology, Metabochip, was designed as a cost-effective way to find and map genomic regions for a range of cardiovascular and metabolic characteristics on a large scale. Previous approaches were not cost effective and tested only 30-40 DNA sequence variations, but this chip allowed researchers to look at up to 200,000 DNA sequence variations for many different traits at one time. The team hoped to find new variants influencing blood glucose and insulin traits and to identify pathways involved in the regulation of insulin and glucose levels.
“We wanted to use this improved Metabochip technology to see whether we could find additional genomic associations that may have been previously missed. Our earlier work identified 23 genetic regions associated with blood glucose levels, highlighting important biological pathways involved in the regulation of glucose. At that stage, and before the design of the Metabochip, we were still limited by our capacity to quickly follow-up and afford parallel genotyping of promising, but unconfirmed genetic regions associated with glucose levels in many different studies across the world.”
Dr Claudia Langenberg Co-lead author from the Medical Research Council Epidemiology Unit, Cambridge
The team combined data from new samples typed on the Metabochip with data from a previous study to discover genetic regions associated with blood glucose and insulin levels. They identified 38 previously unknown regions for three different quantitative traits associated with blood glucose levels; fasting glucose concentrations, fasting insulin concentrations and post-challenge glucose concentrations.
“Our research is beginning to allow us to look at the overlap between genomic regions that influence insulin levels and other metabolic traits. We observed some overlap between the regions we identified and genetic regions associated with abdominal obesity and various lipid levels, which are a hallmark of insulin resistance. We hope that these studies will help to find gene networks with potential key modifiers for important metabolic processes and related diseases, such as type 2 diabetes.”
Dr Inga Prokopenko Co-lead author from the University of Oxford
The team also found many more, less significant, genetic regions that may be associated with blood glucose and insulin levels but currently don’t have the available data to definitively establish them as genome-wide significant. This supports previous evidence that there is a long tail of many other genetic regions that add up to quite small genetic effects but may increase the risk of such diseases as diabetes. Collectively, these less significant associations may represent important blood glucose and insulin level associations.
“In addition to these top signals there is statistical evidence that many other regions that appear to be biologically plausible also influence these traits, but what’s limiting is that we don’t have large enough sample sizes to have the power to validate them. Nevertheless, studying these functionally would be extremely beneficial if we want to fully understand the biology of blood glucose levels and the origin of diabetes.
“What we’ve found in this study is a number of genomic regions that influence blood glucose and insulin traits. Further analysis such as genetic mapping or ‘fine-mapping’ and functional analysis will expand and improve our understanding of the control of glucose and insulin levels in healthy persons and what goes wrong in type 2 diabetes patients.”
Dr InĂªs Barroso Co-lead author from the Wellcome Trust Sanger Institute
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Medical Research Council
For almost 100 years the Medical Research Council has improved the health of people in the UK and around the world by supporting the highest quality science. The MRC invests in world-class scientists. It has produced 29 Nobel Prize winners and sustains a flourishing environment for internationally recognised research. The MRC focuses on making an impact and provides the financial muscle and scientific expertise behind medical breakthroughs, including one of the first antibiotics penicillin, the structure of DNA and the lethal link between smoking and cancer. Today MRC funded scientists tackle research into the major health challenges of the 21st century.
Oxford University
Oxford University’s Medical Sciences Division is one of the largest biomedical research centres in Europe, with over 2,500 people involved in research and more than 2,800 students. The University is rated the best in the world for medicine, and it is home to the UK’s top-ranked medical school.
From the genetic and molecular basis of disease to the latest advances in neuroscience, Oxford is at the forefront of medical research. It has one of the largest clinical trial portfolios in the UK and great expertise in taking discoveries from the lab into the clinic. Partnerships with the local NHS Trusts enable patients to benefit from close links between medical research and healthcare delivery.
A great strength of Oxford medicine is its long-standing network of clinical research units in Asia and Africa, enabling world-leading research on the most pressing global health challenges such as malaria, TB, HIV/AIDS and flu. Oxford is also renowned for its large-scale studies which examine the role of factors such as smoking, alcohol and diet on cancer, heart disease and other conditions.
The Wellcome Trust Sanger Institute
The Wellcome Trust Sanger Institute is one of the world’s leading genome centres. Through its ability to conduct research at scale, it is able to engage in bold and long-term exploratory projects that are designed to influence and empower medical science globally. Institute research findings, generated through its own research programmes and through its leading role in international consortia, are being used to develop new diagnostics and treatments for human disease.
The Wellcome Trust
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