Researchers develop first genetic maps for disease-linked DNA repeats

A research team led by the University of California, Irvine has built the first genetic reference maps for short lengths of DNA repeated multiple times which are known to cause more than 50 lethal human diseases, including amyotrophic lateral sclerosis, Huntington’s disease and multiple cancers.

The UC Irvine Tandem Genome Aggregation Database enables researchers to study how these mutations – called tandem repeat expansions – are connected to diseases, to better understand health disparities and to improve clinical diagnostics.

The study, published online today in the journal Cell, introduces the UC Irvine TR-gnomAD, which addresses a critical gap in current biobank genome sequencing efforts. Although TR expansions constitute about 6 percent of our genome and substantially contribute to complex congenial conditions, scientific understanding of them remains limited.

This groundbreaking project positions UC Irvine as a leader in human and medical genetics by addressing the critical gap in the ability to interpret TR expansions in individuals with genetic disorders. The TR-gnomAD advances our ability to determine how certain diseases might affect diverse groups of people based on variations in these mutations among ancestries. Genetic consulting companies can then develop products to interpret this information and accurately report how certain traits might be linked to different groups of people and diseases.”

Wei Li, the Grace B. Bell Chair and professor of bioinformatics and co-corresponding author

To build the database, the team utilized two software tools to analyze the genomic data of 338,963 participants across 11 sub-populations. Of the .91 million TRs identified, .86 million were of high enough quality to be retained for further study. It was also discovered that 30.5 percent of them had at least two common alternative forms of a gene caused by a mutation located in the same place on a chromosome.

“Although we’ve successfully genotyped a substantial number of TRs, that is still just a fraction of the total number in the human genome,” Li said. “Our next steps will be to prioritize the integration of a greater number of high-quality TR and include more underrepresented ancestries, such as Australian, Pacific Islander and Mongolian, as we move closer to realizing personalized precision medicine.”

UC Irvine team members involved in the research included co-corresponding author and research assistant professor Ya Cui; Wenbin Ye, postdoctoral scholar; Jason Sheng Li, biological chemistry graduate student; and Eric Vilain, professor of pediatrics and the director of the Institute for Clinical and Translational Science. Also participating were Jingi Jessica Le, UCLA biostatistics professor, and Dr. Tamer Sallam, vice chair and associate professor at the UCLA David Geffen School of Medicine.