Photo of Dr. Snyder.

Photo by Steven Fisch: Michael Snyder collaborated with col-
leagues at Stanford and several other institutions to better
understand how genes are regulated across different species.

Stanford Medicine News Center - August 27th, 2014 - by Krista Conger

Fruit flies and roundworms have long been used as model organisms to learn more about human biology and disease. Now, researchers at the Stanford University School of Medicine have found that although many aspects of regulatory networks are conserved among the three distantly related organisms, other differences have emerged over evolutionary time.

These differences may explain why, for example, worms slither, flies fly and humans walk on two legs, even though they all use the same basic genetic building blocks.

“We’re trying to understand the basic principles that govern how genes are turned on and off,” said Michael Snyder, PhD, professor and chair of genetics at Stanford. “The worm and the fly have been the premier model organisms in biology for decades, and have provided the foundation for much of what we’ve learned about human biology. If we can learn how the rules of gene expression evolved over time, we can apply that knowledge to better understand human biology and disease.”

The research was conducted as part of a multi-institutional collaborative effort to understand more about how organisms control the expression of their genes to generate neurons, muscles, skin, blood and all of the other types of cells and tissues necessary for complex life — all at the exactly right time and place in the body.

The research is an extension of the ENCODE, or Encyclopedia of DNA Elements, project that was initiated in 2003. As part of the large collaborative project, which was sponsored by the National Human Genome Research Institute, researchers published more than 4 million regulatory elements found within the human genome in 2012. Known as binding sites, these regions of DNA serve as landing pads for proteins and other molecules known as regulatory factors that control when and how genes are used to make proteins.

The new effort, known as modENCODE, brings a similar analysis to key model organisms like the fly and the worm. Snyder is the senior author of two of five papers published Aug. 28 in Nature describing some aspects of the modENCODE project, which has led to the publication, or upcoming publication, of more than 20 papers in a variety of journals.

Postdoctoral scholar Carlos Araya, PhD, is the lead author of one of the Stanford papers, which mapped the binding sites and cellular expression patterns of 92 regulatory factors in the laboratory roundworm C. elegans. Postdoctoral scholar Alan Boyle, PhD, shares lead authorship with Araya on the second paper, which compares the newly generated roundworm data with human and fruit fly regulatory factors to identify regions of similarity and difference among the organisms. Research associate Trupti Kawli, PhD, coordinated the research in the Snyder lab and is a co-author of both papers.

Of flies, worms and humans

The researchers compared this information between the fly and the worm at several stages of development to learn which proteins and DNA regions are most important at each stage. They also identified which individual cells within the worm were generating, and using, the regulatory factors at each stage.

“For the first time we’re now able to follow in detail where and when particular regions in the genome are used to regulate gene expression, and we can map the cells in which they are operating with an unprecedented level of accuracy,” said Snyder, who is also the Stanford W. Ascherman, MD, FACS, Professor in Genetics.

Many of the regulatory networks or “rules” identified by the researchers are shared among the three organisms. For example, most genes in all three organisms have what are known as HOT — high-occupancy target — spots in nearby DNA. These HOT spots contain clusters of regulatory regions important for the control of gene expression. However, the identities of the regulatory elements bound to the sites differed according to the stage of development of the organism, the cell type and the three-dimensional structure of the DNA at that location.

The exact protein players and DNA sequences involved in binding to or serving as the HOT spots also often differed among human, fly and worm — perhaps reflecting different evolutionary pressures. Those differences are a likely reason why flies, worms and humans are so distinct in shape, size, and behavior for example.

Fueling future research

The wealth of data from the modENCODE project will fuel research projects for decades to come, according to Snyder.

“We now have one of the most complete pictures ever generated of the regulatory regions and factors in several genomes,” said Snyder. “This knowledge will be invaluable to researchers in the field.”

Additional Stanford authors are postdoctoral scholars Dan Xie, PhD, and Yong Cheng, PhD; research assistants Lixia Jiang and Beijing Wu; former research associate Cathleen Brdlik, PhD; software developer Philip Cayting; and assistant professor of genetics and of computer science Anshul Kundaje, PhD.

The study was supported by the National Human Genome Research Institute (grants U01HG004264, RC2HG005679, P50GM081892, U54HG006996, U54HG004558, U01HG004267 and F32GM101778).

Information about Stanford’s Department of Genetics, which also supported the work, is available at http://genetics.stanford.edu.

Originally published at Stanford Medicine News Center