This is a very interesting report that could have an impact on identifying and intervening with diabetics who are most likely to have kidney failure.
Take home summary:
1. The gene (CNDP1) codes for an enzyme (carnosinase 1) that deactivates a substance (carnosine) that protects the kidneys from scarring. Carnosine is also a free radical scavenger.
2. A variant of the carnosinase gene is associated with lower risk of kidney failure in diabetes and is found in a proportion of Caucasians (Europeans, American whites and Arabs), but not in African Americans. Authors speculate that kidney failure in blacks may be due to differences in carnosine metabolism or a different mechanism or pathway.
3. Implications are that individuals with diabetes who have the greatest risk for kidney failure may be identified and interventions developed to prevent or ameliorate kidney damage, either by increasing carnosine levels or by interfering with the enzyme that deactivates it.
This research was done at Wake Forst Unversity and the University of Heidelberg. It is published online as an article in Nephrology Dialysis Transplantation
. See below for the full press release from Wake Forest University.
Researchers Identify Gene Associated with Severe Kidney Failure in Diabetes
WINSTON-SALEM, N.C. - A research team at Wake Forest University Baptist Medical Center and the University of Heidelberg has proven that a gene protects some people with diabetes from developing severe kidney failure or "end-stage renal disease."
Diabetes is the leading cause of end-stage kidney disease worldwide, an illness that requires either kidney dialysis treatments or a kidney transplant for survival.
The carnosinase 1 gene, located on human chromosome 18, produces the protective factor, said Barry I. Freedman, M.D., the John H. Felts III Professor and head of the Section on Nephrology, in an article in Nephrology Dialysis Transplantation published online.
This is a major gene that appears to be associated with development of severe diabetic kidney disease, he said.
The research team evaluated 858 subjects, including diabetic patients with end-stage kidney failure on dialysis, diabetic patients with normal kidney function, and healthy non-diabetic individuals. They confirmed that a protective form of the carnosinase 1 gene was present in greater frequency among both healthy individuals and diabetic subjects without kidney disease, compared to the diabetic patients on dialysis who more commonly had forms of the gene that were not protective.
This discovery may lead to novel treatment strategies in susceptible diabetic patients to protect them from kidney failure may provide a marker to determine which diabetic patients are at increased risk for future kidney disease, Freedman said.
The carnosinase 1 gene produces an enzyme called carnosinase. Carnosinase inactivates the protective substance carnosine. Carnosine appears to prevent scarring from developing in kidney tissue and serves as a scavenger of damaging oxygen-free radicals.
Prior to these genetic analyses, kidney doctors were unaware that this pathway played an important role in diabetic kidney disease, Freedman said.
He added that the groups at Wake Forest and in Germany had been looking for the gene or genes after concluding that a region on chromosome 18 was important in predisposing people who have type 2 diabetes (adult onset diabetes) to the development of severe kidney failure. Freedman said the actions of this gene apply to Europeans, American whites and Arabs.
When his group repeated the analysis in black Americans, there was no evidence that the carnosinase pathway was involved in their kidney failure.
It is possible that American blacks have different carnosine metabolism, making them less susceptible to alterations in carnosinase gene activity. Analyses are currently under way, said Freedman. It is also possible that an additional gene or genes on chromosome 18 is associated with susceptibility to end-stage kidney disease in black Americans, and our group is actively trying to identify them.
Freedman said that among people who are susceptible to kidney failure, it will be important to evaluate whether the administration of carnosine or agents that inhibit carnosinase activity will protect diabetic individuals from the development of progressive kidney disease.
He said that while carnosine is available over the counter in health food stores, it is possible that excessive carnosinase enzyme activity could prevent carnosine supplementation from protecting the kidney. As such, carnosinase blockers may prove to be more important.
Freedman noted that Wake Forest researchers "have one of the largest existing collections of DNA samples from black and white families with multiple members having end-stage kidney disease. We have been evaluating these families since 1991.
Besides Freedman, the research team includes Donald W. Bowden, Ph.D., Pamela J. Hicks, B.S., Michele M. Sale, Ph.D., Eric F. Pierson, M.D., Carl D. Langefield, Ph.D., Stephen S. Rich, Ph.D., Jianzhao Xu, B.S., and Caitrin McDonough, B.S., all from Wake Forest, Bart Janssen, M.D., and Benito A. Yard, M.D., from the Institute of Human Genetics in Heidelberg, Germany, and Fokko J. van der Woude from Fifth Medical Department, University Clinic (Universit√§tsklinikum), Mannheim Germany.
Source: http://www.wfubmc.edu ( http://www.wfubmc.edu/ )