New Method of Identifying Molecules Could Help to Prevent Diabetes

Pancreatic beta cells produce insulin, responsible for controlling blood sugar levels and thus essential for our survival. Among the numerous factors that affect the workings of these cells, a protein called Cx36 was identified a few months ago by a research team at the University of Geneva (UNIGE). Scientists demonstrated that in transgenic mice, suitably modified to not produce any Cx36, synchronization of the beta cells ceased and insulin production went out of control. This de-synchronization of insulin secretion is the first measurable sign in people suspected of developing type 2 diabetes. Armed with this knowledge, the research team is now looking for molecules which act directly on Cx36 with the objective of developing a novel therapeutic approach to fighting diabetes.

Paolo Meda, Professor of Cellular Physiology and Metabolism in UNIGE's Faculty of Medicine, set his team a real challenge - study the protein Cx36, present in minute quantities and almost impossible to detect using traditional techniques, and which has a half-life of around three hours.

Sabine Bavamian and Helena Pontes, researchers in Professor Meda's laboratory, are working on developing a non-invasive system for understanding how Cx36 works. This project has been partly financed by the Juvenile Diabetes Research Foundation (USA) and the Swiss National Science Foundation and is using equipment in the Bio-Imaging department of UNIGE's Faculty of Medicine. The two scientists have been able to develop a new model using living cells which produce insulin and Cx36 in culture in order to be able rapidly to test a large number of potentially interesting molecules. With this novel approach, they have been able to analyze some 1040 molecules, enabling them to identify those that stimulate insulin production and those that inhibit it. Such discoveries should enable the roll-out of new pharmacological treatment strategies for type 2 diabetes.

Although there are now a large number of drugs that are prescribed for diabetics the world over to help alleviate insulin secretion de-synchronization, the majority of them have unfortunate side effects. And thus Professor Meda has decided to use the innovative technique developed by his team to test the effect on Cx36 of very different molecules, produced from animal venom. Such molecules should not give rise to the same type of problem posed by the traditional drugs used currently. The screening, or selection, of the venom should enable carrying out the necessary validation tests, initially in vitro, and then in vivo. "We have some 3 to 5 years work ahead of us, but we have very serious hopes of discovering molecules which act exclusively on Cx36, unlike all the currently identified molecules, with a view to limiting side-effects," explains Professor Meda.