Scientists discover mechanism that controls obesity, atherosclerosis and potentially cancer

July 3, 2012

Scientists from the Institute of Molecular and Cell Biology (IMCB) have discovered a new signalling pathway that controls both obesity and atherosclerosis. The team demonstrated, for the first time, that mice deficient in the Wip1 gene were resistant to weight gain and atherosclerosis via regulation of the Ataxia telangiectasia mutated gene (ATM) and its downstream signalling molecule mTor. These groundbreaking findings were published in the journal Cell Metabolism on 3rd July and may provide significant new avenues for therapeutic interventions for obesity and atherosclerosis.

Obesity and atherosclerosis-related diseases account for over one-third of deaths in the Western world. Controlling these conditions remains a major challenge due to an incomplete understanding of the involved. Atherosclerosis, a of the large arteries, is an underlying cause of many cardiovascular diseases. In Singapore, 10.8% of our population is obese and cardiovascular disease accounted for 31.9% of all deaths in 2010.

Obesity and atherosclerosis are accompanied by the accumulation of lipid droplets in adipocytes () and in foam cells respectively. can subsequently rupture, damaging blood vessels, and contributing to further progression of atherosclerosis. The scientists discovered that Wip1 deficient mice, even when fed a high-fat diet, were resistant to obesity and atherosclerosis by preventing the accumulation of lipid droplets. This appeared to be through increased autophagy, the normal process by which the body degrades its own . They showed that the Wip1 deficient mice exhibited increased activity of ATM which decreased mTor signalling, resulting in increased autophagy. This degraded the and suppressed obesity and atherosclerosis.

“This is the first time that Wip1-dependent regulation of ATM-mTor pathway has been linked to authophagy and cholesterol efflux thus providing an entirely new avenue for treatment of obesity and atherosclerosis,” said Dr Dmitry Bulavin, Senior Principal Investigator at IMCB and lead author of this paper.

Mapping the mechanism to cancer

The scientists are hopeful that this ATM-mTor pathway could similarly map onto cancer to suppress tumour progression. Similar to suppression of obesity and atherosclerosis, activation of autophagy in cancer cells could result in degradation of cellular content that is essential for cancer cells to sustain rapid proliferation. This, in turn, will result in suppression of cancer growth.

Said Dr Dmitry Bulavin, “We are building on this research to investigate if the same mechanism could also control tumour progression and hence potentially unlock new therapeutic treatments targeting Wip1, ATM and mTor in cancer as well and the preliminary results are promising.”

This discovery also adds to the growing significance of ATM as an important gene with a key role in protecting us from major pathological conditions. Previous work has established Wip1-dependent regulation of ATM as a potent regulator of tumorigenesis via activation of tumour-suppressor p53. Together, these three pathological conditions - obesity, atherosclerosis and cancer - account for more than 70% of mortality worldwide, making ATM-related pathways very attractive therapeutic targets.

Prof Hong Wanjin, Executive Director of IMCB, said, “This is the first time that these important molecules have been integrated into a linear pathway that plays a prominent role in controlling obesity and atherosclerosis. It is a fine example of how fundamental research can shed light on biological and medical questions to potentially open new avenues of formulating therapeutic strategies for the benefit of patients.”

Explore further: 2 heads are better than 1: 2 dysfunctional DNA repair pathways kill tumor cells

More information: The research findings described in this news release can be found in the July 3 print issue of Cell Metabolism under the title “Wip1-dependent regulation of autophagy, obesity and atherosclerosis” by Xavier Le Guezennec et al.

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