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Mouse model for diabetic kidney disease suggests role for immune and inflammatory pathways

Posted: 12 November 2018 | | No comments yet

Scientists have designed mice that successfully emulate a severe form of kidney damage in humans with diabetes, called diabetic nephropathy…

Scientists have designed mice that successfully emulate a severe form of kidney damage in humans with diabetes, called diabetic nephropathy. Genetic analyses of the mice led to the surprising finding that expression of genes controlling immune and inflammatory responses may play a causal role in promoting kidney damage, and suggest these pathways might be promising targets for therapy.

Kidney damage in people with diabetes can lead to life-threatening kidney failure. In Singapore, diabetes is the leading cause of end-stage kidney disease requiring dialysis. There are strong ethnic and familial associations for kidney disease in diabetes, indicating a role of genetic factors in determining susceptibility. However, identifying the precise genes involved in diabetic nephropathy has been problematic.

To learn more about the disease, researchers have worked for years to develop animal models recapitulating features of kidney disease seen in humans, as an approach for identifying its root causes in order to improve diagnosis and treatment for diabetics who have kidney complications. However, diabetic mice typically only develop minimal kidney damage.

To develop a mouse model more closely recapitulating diabetic nephropathy in humans, Professor Thomas Coffman, Dean of Duke-NUS Medical School and a Nephrologist, and colleagues combined Type I diabetes with over-activation of a hormone system, called the renin-angiotensin system, which is known to be overly activated in humans with diabetic kidney disease.

To reproduce the differences in genetic susceptibility to nephropathy seen in human diabetes, the team used two different strains of mice known to have different propensities for developing kidney disease. Using these two different strains provided a “powerful system” for identifying mechanisms associated with the development of nephropathy.

The team analysed the genes expressed in glomeruli, the filtering units of the kidney and a primary site of damage in diabetes. They found that clusters of genes associated with activation of the immune system and inflammatory responses were turned on in the susceptible strain of mice, but were not activated in the strain that was resistant to kidney damage.

“Our data suggest that inflammation and immune responsiveness may be critical features in determining susceptibility to kidney disease in diabetes,” Prof Coffman concluded.

As there are a number of available drugs for inhibiting the immune system and inflammation, the findings suggest that targeting these pathways might be useful for preventing or slowing the development of diabetic nephropathy.

“Although the precise genetic determinants of susceptibility and resistance to diabetic nephropathy may differ between mice and humans, it is likely that the molecular pathways involved are similar,” the researchers say. “Such pathways are attractive as biomarkers for disease susceptibility and targets for therapy.”

The study is among a crop of new research on diabetes supported by DYNAMO (Diabetes Study in Nephropathy And other Microvascular Complications), which was launched in 2017, with Prof Coffman as the lead principal investigator, and involves 25 leading healthcare and research institutions across six countries, including Singapore. “DYNAMO focuses basic, clinical and translational research to improve our understanding of diabetes and its complications,” explained Prof. Coffman, “and discover new ways to prevent and manage these to improve the lives of those affected and at risk of the disease.”

The researchers explain their study in the journal Diabetes.