A model for development: biologists create first predictive computational model of gene networks

Aug 29, 2012 by Marcus Woo
A model for development
This image of a sea-urchin embryo shows where two different regulatory genes are being expressed, labeled in fluorescent green and red. Credit: Caltech/Isabelle Peter

(Phys.org)—As an animal develops from an embryo, its cells take diverse paths, eventually forming different body parts—muscles, bones, heart. In order for each cell to know what to do during development, it follows a genetic blueprint, which consists of complex webs of interacting genes called gene regulatory networks.

at the California Institute of Technology (Caltech) have spent the last decade or so detailing how these control development in sea-urchin embryos. Now, for the first time, they have built a computational model of one of these networks.

This model, the scientists say, does a remarkably good job of calculating what these networks do to control the fates of different cells in the early stages of sea-urchin development—confirming that the interactions among a few dozen genes suffice to tell an embryo how to start the development of different in their respective spatial locations. The model is also a powerful tool for understanding gene in a way not previously possible, allowing scientists to better study the genetic bases of both development and evolution.

"We have never had the opportunity to explore the significance of these networks before," says Eric Davidson, the Norman Chandler Professor of at Caltech. "The results are amazing to us."

A model for development
Caltech researchers built the first-ever computational model of the gene regulatory network controlling sea-urchin embryonic development. A small part of the network is shown here. Credit: Caltech/Davidson Lab

The researchers described their in a paper in the that appeared as an advance online publication on August 27.

The model encompasses the gene regulatory network that controls the first 30 hours of the development of endomesoderm cells, which eventually form the embryo's gut, skeleton, muscles, and immune system. This network—so far the most extensively analyzed developmental gene regulatory network of any animal organism—consists of about 50 regulatory genes that turn one another on and off.

To create the model, the researchers distilled everything they knew about the network into a series of logical statements that a computer could understand. "We translated all of our biological knowledge into very simple Boolean statements," explains Isabelle Peter, a senior research fellow and the first author of the paper. In other words, the researchers represented the network as a series of if-then statements that determine whether certain genes in different cells are on or off (i.e., if gene A is on, then genes B and C will turn off).

By computing the results of each sequence hour by hour, the model determines when and where in the embryo each gene is on and off. Comparing the computed results with experiments, the researchers found that the model reproduced the data almost exactly. "It works surprisingly well," Peter says.

Some details about the network may still be uncovered, the researchers say, but the fact that the model mirrors a real embryo so well shows that biologists have indeed identified almost all of the genes that are necessary to control these particular developmental processes. The model is accurate enough that the researchers can tweak specific parts—for example, suppress a particular gene—and get computed results that match those of previous experiments.

Allowing biologists to do these kinds of virtual experiments is precisely how computer models can be powerful tools, Peter says. Gene regulatory networks are so complex that it is almost impossible for a person to fully understand the role of each gene without the help of a , which can reveal how the networks function in unprecedented detail.

Studying gene regulatory networks with models may also offer new insights into the evolutionary origins of species. By comparing the gene regulatory networks of different species, biologists can probe how they branched off from common ancestors at the genetic level.

So far, the researchers have only modeled one network, but their goal is to model the networks responsible for every part of a sea-urchin embryo, to build a model that covers not just the first 30 hours of a sea urchin's life but its entire embryonic development. Now that this modeling approach has been proven effective, Davidson says, creating a complete model is just a matter of time, effort, and resources. 

Explore further: Canola genome sequence reveals evolutionary 'love triangle'

More information: The title of the PNAS paper is "Predictive computation of genomic logic processing functions in embryonic development."

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nanotech_republika_pl
not rated yet Aug 29, 2012
A tool like this for human embryo development will some day help understand the cancer cell in human (the stem cells regain the embryo-like when cancerous).
extinct
1 / 5 (1) Aug 30, 2012
LOL, you gotta love the headline in this article, because it reveals way more than was intended: "Biologists create first predictive computational model of gene networks." OK, if this is the *first* predictive model of gene networks, then what does that tell you about genetically modified organisms in use for 39 years? none of those have been predictive, if this is the first predictive one. that fits perfectly in line with something else the establishment is working hard to keep you from knowing: ONE gene, changed in ONE organism (like an apple for example) causes THOUSANDS of changes. of those thousands of changes, only ONE is advertised. for example "our GMO apple will not go brown!" the white lie involved, however, is a big one. if they were completely 100% honest, they'd say "our GMO apple *accidentally* does not go brown, and has thousands of other un-natural attributes, which we can predict nothing about because those are non-predictive. now eat it, or else! we want your $$$!"