Diabetes Molecular Study Advances
Diabetes Molecular Study Advances. A scientific study published on the journal Diabetes, edited by the American Diabetes Association, describes for the first time the pharmacological action of thiazolidinediones (TZDs) — anti-diabetic drugs — directly on the pancreas, the organ which produces insulin.
The research, carried out with laboratory animal models, is led by the professor Carme Caelles, from the Cell Signaling Research Group from the Department of Biochemistry and Molecular Biology (Faculty of Pharmacy), together with the team of Dr Ramon Gomis, from the Hospital Clínic of Barcelona — IDIBAPS.
Insulin is the main hormone which regulates blood glucose levels. When the pancreas does not produce enough insulin, type 1 diabetes takes place, which usually requires a daily administration of insulin. On the contrary, type 2 diabetes is caused by a problem in the way your body uses insulin (resistance to this hormone) and is associated with overweight and physical inactivity.
Type 2 diabetes: a public health issue
The article published in Diabetes analyzes type 2 diabetes: the most common form of diabetes (85-90 % of diabetics). Often, people with type 2 diabetes have no symptoms at first, but it ends up producing hyperglycemia due to insulin resistance. In other words, in this type of diabetes, tissues do not answer to this hormone signal and, consequently, cells are not able to absorb insulin (the main body source of energy). So, pancreatic β-cells produce extra insulin which results in pancreatic hyperplasia.
In the pharmacological field, type 2 diabetes can be treated with some drugs such as sulfonylureas, which increase insulin production and facilitate glucose absorption to cell metabolism (anti-hyperglycemic action). Other drugs, for example metformin, can also help as they limit the glucose synthesis carried out by the liver.
Studying molecular signaling pathways
The work is focused on the action of thiazolidinediones (TZDs), oral anti-diabetic drugs which reduce insulin resistance and exert insulin-sensitizing action directly on tissues. According to the professor Carme Caelles, at her laboratory in the Barcelona Science Park, “the action mechanism of TZDs is not well known yet. Their receptor (the PPARγ) has been identified; but we do not know yet how they act at molecular level.”
In a previous article, published on Diabetes in 2007, researchers proved that TZDs inhibit JNK kinase (c-Jun N-terminal kinase), a transducer of biochemical signals which inhibit insulin signaling and is related to insulin resistance. “Then — added Caelles — , we proved that the pharmacological action of TZDs includes JNK inhibition and this effect is more effective on adipose tissues, where PPARγ is mostly expressed.”
Is TZDs action also effective on the pancreas?
The authors of the study have provided the first evidence of TZD’s pharmacological action on pancreatic β cells — insulin producers — and shown new research lines on the action of these drugs to control glucose metabolism. The study generated a transgenic mouse model that allows JNK activation in tissues which has been an excellent in vivo model to prove the action mechanism of TZD drugs.
The conclusions stated that JNK activation is necessary to generate insulin resistance — in pancreatic β-cells — which generates a glucose intolerance phenotype in the mice experimental model. Curiously, this phenotype does not correlate with any obvious morphological or structural abnormality in the pancreas or the islets. In fact, despite previous literature, pancreatic β-cells do not die exclusively by JNK activation.
Caelles remarks that “we knew that pancreatic β-cells also have the receptor PPARγ, but now we know that TZDs have a role in central insulin resistance. All the pharmacological actions described were attributed to the receptor expression in peripheral tissues, such as the adipose (peripheral insulin resistance).”
Diabetes, obesity and inflammation
Many scientific studies prove a connection among molecular signaling pathways of diabetes, obesity and inflammation. “During an inflammation process, JNK kinase is also activated,” explains Caelles. “In type 2 diabetes” he explains, “the extra insulin demand generates a pancreatic hyperplasia which causes inflammation. Obesity is also related to a low-grade, chronic inflammatory state, this could explain its link with insulin resistance. Therefore, in obesity, adipose tissue catches cells of the immune system, and increases the levels of inflammation mediators (interleukins, etc.). As JNK kinase is active during all this process, insulin is not able to regulate glucose metabolism.”
The scientific team led by Carme Caelles mainly studies the regulation mechanism of the different signaling pathways in cell processes which are fundamental for metabolism. Taking into account the last scientific results, the team is fostering new research lines with animal models to analyze the physiologic and biochemical answer of β-cells in extreme conditions, and to know the evolution of insulin resistance mechanism in aging.
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Journal Reference: J. Lanuza-Masdeu, M. I. Arevalo, C. Vila, A. Barbera, R. Gomis, C. Caelles. In vivo JNK activation in pancreatic -cells leads to glucose intolerance caused by insulin resistance in pancreas. Diabetes, 2013; DOI:10.2337/db12-1097