Obesity
often triggers diabetes. The molecular changes induced by this metabolic
condition, as well as the drugs used to treat it, can now be traced, paving the
way to personalized therapy.
The recently developed ability to chart the
molecular progress of diabetes brings much-needed personalized medicine closer
to realization
Researchers in Singapore have succeeded in
tracking, for the first time, the molecular changes caused by type 2 diabetes
that affect how the body handles glucose production in the liver1. In a series
of experiments in mice, the researchers introduced a form of the compound
pyruvate that incorporated specially treated carbon nuclei. This allowed the
researchers to follow the processing of the compound using magnetic resonance
spectroscopy (MRS). In this way, the team, led by Phillip Lee of the Singapore
Bioimaging Consortium, showed that the enzyme pyruvate carboxylase plays a key
role in the development of diabetes.
The researchers also used their technology to
plot the molecular changes induced by diabetes treatment over time. “This
facilitates an in-depth understanding of treatment response in each subject and
paves the way for personalized treatment,” Lee says.
Diabetes is a consequence of the dysfunction
of insulin, a hormone that stimulates cellular uptake of glucose from the
blood. This process is closely linked to the production of glucose in the
liver. Since the 1980s, limited study of the molecular details of glucose
production has been possible using MRS to track organic compounds incorporating
the rarer type of natural carbon known as carbon-13. Recently a
‘hyperpolarized’ form of carbon-13 — vastly easier to detect using MRS — has
become available.
Lee and his co-workers injected
hyperpolarized carbon-13-labeled pyruvate into a strain of mice in which type-2
diabetes can be induced simply by changing the diet from normal to high fat.
Using MRS, they then traced over time, in both normal and diabetic mice, the
compounds into which the hyperpolarized carbon nuclei became incorporated, and
in what proportions. Their results provide evidence not only of which
biochemical pathways are active, but also which are dominant in normal and
diabetic mice.
By comparing the two groups of mice, they
were able to show distinct changes in the liver metabolism of diabetic mice
over time, particularly the importance of the biochemical pathway dependent on
the enzyme pyruvate carboxylase in the development of diabetes. When the
researchers gave the mice drugs typically used to treat diabetes, their
technique detected the metabolic changes resulting from the therapy.
“This technology could be used to screen for
metabolic disorders associated with other conditions such as heart failure,
cancers and brain diseases,” Lee says. “We are extending our work to
investigate metabolic aberrations in the diabetic heart, and to understand the
therapeutic effects of anti-diabetic drugs on cardiac function.”
The A*STAR-affiliated researchers
contributing to this research are from the Singapore Bioimaging Consortium
References
- Lee, P., Leong, W., Tan, T., Lim, M., Han, W.
& Radda, G. K. In vivo hyperpolarized carbon-13
magnetic resonance spectroscopy reveals increased pyruvate carboxylase
flux in an insulin resistant mouse model.Hepatology advance
online publication, 22 August 2012 (doi: 10.1002/hep.26028). | article
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