Press release issued 31 January 2013
Researchers describe key mechanism responsible for brain’s regulation of obesity-associated disease
Obesity and its related conditions such as type 2 diabetes, cardiovascular disease and stroke are among the most challenging of today’s healthcare concerns. Together, they constitute the biggest killer in western society. New findings, published in Cell, have identified a target that could hold the key to developing safe therapies to treat obesity and its associated conditions.
Although recent research has begun to unravel some of the pathways that control how information is processed by our nervous system regulating body weight and cardiovascular function, the exact mechanisms through which signals are sensed by the brain and translated into co-ordinated metabolic and cardiovascular responses remain unclear.
A University of Bristol team, with funding from the British Heart Foundation (BHF), has now identified that a target found to be critical in the brain’s regulation of body weight, is also crucially involved in the development of obesity-associated conditions. Researchers describe the mechanism behind a key molecule, known as melanocortin-4-receptor (MC4R), whose mutation or loss in both human and animal models has shown to cause severe obesity with type 2 diabetes.
While previous studies have shown that small activators of the molecule, which increase MC4R activity, have the desirable effect of reducing food intake and insulin secretion from the pancreas (important to suppress the development of type 2 diabetes), it is not clear how, at the same time, they trigger the undesirable effect of increasing blood pressure.
The team has now identified a mechanism for MC4R-mediated regulation of the activity of the autonomic nervous system to maintain appropriate blood pressure and insulin levels. The autonomic nervous system, which regulates internal organs and processes that are not under our control, is split into the parasympathetic and sympathetic nervous system, commonly exerting opposing influences on the structures they supply with nerves.
Researchers demonstrated that the activation of the MC4R inhibits parasympathetic neurons in the brain stem area of the central nervous system (CNS), while activating sympathetic neurons in the spinal cord. The team further demonstrates, in genetically-modified mouse models of human loss of MC4R function, that MC4Rs in these CNS areas are to blame for the development of obesity-induced increases in blood pressure.
They also report that MC4Rs in these CNS areas are pivotal in maintaining appropriate insulin levels to stave off type 2 diabetes. Thus, by carefully balancing positive and negative forces on the autonomic nervous system, the MC4R maintains equilibrium of appropriate blood pressure and insulin levels. This is independent of the MC4R’s role in the regulation of food intake elsewhere in the CNS.
MC4R is a target of intense pharmaceutical interest and the data from this research helps in our understanding of the CNS mechanisms regulating homeostatic body weight, blood pressure and insulin levels through a distributed network of MC4Rs. These findings may facilitate the development of appropriate, safe therapies to treat obesity and its associated conditions.
Dr Nina Balthasar, one of the study’s lead authors and a researcher in the University’s School of Physiology and Pharmacology, said: “Obesity is a major risk factor for cardiovascular disease with recent statistics showing that obese adults are three to four times more likely to develop high blood pressure.
“In order to curb the escalating incidence of obesity and obesity-related diseases, a primary prevention goal must be to understand the physiological processes underlying our vulnerability to weight gain — knowledge that is central to the development of novel, effective therapies.
Our data illustrate the complexity of the CNS pathways governing the body’s metabolic balance and highlight the challenges ahead for the development of safe therapies. “
Dr Shannon Amoils, Research Advisor at the BHF, which part-funded the study, added: “This research increases our understanding of how the nervous system affects our metabolism, and the development of high blood pressure due to obesity. With further knowledge of this complex area we hope scientists will be able to find safe and effective ways of treating obesity-related heart and circulatory disorders.”
The British Heart Foundation and Lister Institute for Preventive Medicine-funded study, entitled ‘Melanocortin-4-Receptors Reciprocally Regulate Sympathetic and Parasympathetic Preganglionic Neurons’ is published in Cell on 31 January 2013.
Recent NHS statistics on obesity, physical activity and diet in England show that just over a quarter of adults (26 per cent of both men and women aged 16 or over) were classified as obese in 2010 (Body Mass Index (BMI) 30kg/m2 or over) with a further 37 per cent classified as overweight (BMI 25-30). High blood pressure was recorded in 51 per cent of obese men compared with 20 per cent in the normal weight group.
Childhood obesity continues to be an acute health crisis, with 30 per cent of children in the UK today aged two to 15 being overweight.
The British Heart Foundation
The British Heart Foundation (BHF) is the nation’s heart charity, dedicated to saving lives through pioneering research, patient care, campaigning for change and by providing vital information. But we urgently need help. We rely on donations of time and money to continue our life-saving work. Because together we can beat heart disease. For more information visit http://www.bhf.org.uk
Obesity is a major risk factor for cardiovascular disease with recent statistics showing that obese adults are three to four times more likely to develop high blood pressure. In order to curb the escalating incidence of obesity and obesity-related diseases, a primary prevention goal must be to understand the physiological processes underlying our vulnerability to weight gain — knowledge that is central to the development of novel, effective therapies. Our data illustrate the complexity of the CNS pathways governing the body’s metabolic balance and highlight the challenges ahead for the development of safe therapies.