Although the human genome is 99 percent the same from human to human, it is that 1 percent that can have a major impact on our response to diseases, viruses, medications, and toxins. If researchers can uncover the minute genetic details that set each of us apart, biomedical research and treatments can be better customized for each individual.

This Behind the Scenes article was provided to LiveScience in partnership with the National Science Foundation.

Imagine being adopted, with no understanding of your cultural or genetic background. You don’t know your heritage or what diseases you are genetically predisposed to. Most of us have some idea about the roots of our family tree, but little understanding of what those lower branches mean in terms of our predisposition to a host of diseases and ailments. Now, a group of computer scientists, mathematicians, and biologists from around the world have developed a computer algorithm that can quickly trace an individual’s genetic ancestry with only a small sample of their DNA. In fact, the program can trace the genetic ancestry of thousands of individuals in minutes, without any prior knowledge of their background. The multi-disciplinary approach, published in the September 2007 edition of the journal PLoS Genetics, allowed the research team to address this type of research in a novel way. Unlike previous computer programs that required prior knowledge of an individual’s ancestry and background, the new algorithm looks for specific DNA markers known as single nucleotide polymorphisms, or SNPs (pronounced snips), and needs nothing more than a DNA sample in the form of a simple cheek swab. The researchers used genetic data from previous studies to perform and confirm their research, including the new HapMap database, which is working to uncover and map variations in the human genome. "This work was an exciting opportunity to form an interdisciplinary team of computer scientists, mathematicians, and human geneticists," said Petros Drineas, the senior author of the study and assistant professor of computer science at Rensselaer Polytechnic Institute. "Now that we have found that the program works well, we hope to implement it on a much larger scale, using hundreds of thousands of SNPs and thousands of individuals," said Drineas, who was funded by an NSF CAREER award. "The program will be a valuable tool for understanding our genetic ancestry and targeting drugs and other medical treatments because it might be possible that these can affect people of different ancestry in very different ways."

Understanding our unique genetic makeup is a crucial step to unraveling the genetic basis for complex diseases. Although the human genome is 99 percent the same from human to human, it is that 1 percent that can have a major impact on our response to diseases, viruses, medications, and toxins. If researchers can uncover the minute genetic details that set each of us apart, biomedical research and treatments can be better customized for each individual, Drineas said. This program will help people understand their unique backgrounds and aid historians and anthropologists in their study of where different populations originated and how humans became such a hugely diverse, global society. The program was more than 99 percent accurate in trials and correctly identified the ancestry of hundreds of individuals. This included people from genetically similar populations (such as Chinese and Japanese) and complex genetic populations like Puerto Ricans who can come from a variety of backgrounds including Native American, European, and African ancestries. "When we compared our findings to the existing datasets, only one individual was incorrectly identified and his background was almost equally close between Chinese and Japanese," Drineas said. Drineas explains that the results are preliminary, but extremely promising. The team is now working to test their program on a much larger data set. In addition to Drineas, the algorithm was developed by scientists from California, Puerto Rico, and Greece. The researchers involved include lead author Peristera Paschou from the Democritus University of Thrace in Greece; Elad Ziv, Esteban G. Burchard, and Shweta Choudhry from the University of California, San Francisco; William Rodriguez-Cintron from the University of Puerto Rico School of Medicine in San Juan; and Michael W. Mahoney from Yahoo! Research in California.

Editor's Note: This research was supported by the National Science Foundation (NSF), the federal agency charged with funding basic research and education across all fields of science and engineering. See the Behind the Scenes Archive.