Researchers say they have found 13 genes linked to human body mass.

Starting with DNA samples extracted from Icelanders' white blood cells banked in 1991 and 2002 by scientists there as part of the AGES–Reykjavik study of individuals in the general population, scientists used a customized, genome-wide profiling method dubbed CHARM (comprehensive high-throughput arrays for relative methylation) to look for regions that were the most variable, all chemically marked by DNA methylation. 

The DNA methylation analyses revealed epigenetic fingerprints which are unique to each individual and remain stable over time and may also be associated with various common traits including risks for common, complex diseases such as cancer and other conditions. 

"Epigenetics has given us 13 exciting new leads to variability in body mass and obesity," says co-lead investigator M. Daniele Fallin, Ph.D., associate professor of epidemiology at the Johns Hopkins Bloomberg School of Public Health. "The team's success suggests a new epigenetic strategy for identifying those at risk for many common diseases, and for possible new prevention methods and therapies."

In their report, the researchers reveal 227 regions within the genome where there's a great deal of variation among individuals. While 41 (about one-third) of these VMRs changed within each person between the 1991 and 2002 DNA analyses, 119 remained stable over time, satisfying the definition of an epigenetic fingerprint, or signature, for each person. 

Curious to know if these signatures were linked to obesity-related disease, the researchers analyzed them in relation to each person's body mass index — a measure of one's weight relative to height. BMI was chosen, Feinberg says, because a high BMI predicts risk for many common diseases in the general population.

The team used BMI data provided by Iceland's AGES–Reykjavik study, which archives detailed information over time about that isolated nation's population, including body compositions and metabolic regulations. "We found a high statistical significance between 13 of these VMRs and body mass index," Fallin says. "The level of methylation at these VMRs is, in fact, related to the person's weight."

The researchers focused their search on the epigenetic mark known as DNA methylation because this chemical change in DNA involves the addition of a methyl (a carbon-and-3-hydrogen atom) group, which, although not contained in the DNA sequence itself, controls when and how genes are turned on and off. Such "switches" signal cells in the body that share the same DNA to assume different functions or forms.

Overall, the team measured DNA methylation levels of 4.5 million selected sites genome-wide in the Iceland DNA samples that were taken 11 years apart, from 74 individuals, ultimately tracking down an array of genes associated with body mass index.

"What we accomplished is a small proof-of-principle study that we think is just the tip of the iceberg in using epigenetics to expand our knowledge of new markers for many common diseases and opening the door for personalized epigenetic medicine," Feinberg says.

"BMI is just a starting point for us," agrees Rafael Irizarry, Ph.D., a professor of biostatistics and co-author of the report. "We want to use the same method to look for genes associated with autism, bipolar disease and variations in aging."

Citation: Jeffrey J. Wallin, Jane Guan, Wei Wei Prior, Kyle A. Edgar, Robert Kassees, Deepak Sampath, Marcia Belvin, Lori S. Friedman, 'Glaciation as a destructive and constructive control on mountain building', Nature 467, 313-317 (16 September 2010) doi:10.1038/nature09365