 |
|
Cells use 'noise' to make cell-fate decisions
March 23, 2007Electrical noise, like the crackle heard on AM radio when lightning strikes nearby, is a nuisance that wreaks havoc on electronic devices. But within cells, a similar kind of biochemical "noise" is beneficial, helping cells transform from one state to another, according to a new study led by a UT Southwestern Medical Center researcher.
Dr. Gürol Süel, assistant professor of pharmacology, said his research and that of his colleagues published today in the journal Science represents "a new paradigm," suggesting that rather than being bad for biology, cellular noise might have an important function, such as prompting stem cells to transform into a specific tissue type.
Electronic noise is an unwanted signal characteristic of all electrical circuits, typically caused by random fluctuations in the electric current passing through the components of a circuit. Similarly, within each living cell there are myriad "genetic circuits," each composed of a distinct set of biochemical reactions that contribute to some biological process. Randomness in those reactions contributes to biological noise, technically referred to as stochastic fluctuations.
"Noise in biological systems is a fact of life," said Dr. Süel, a member of the systems biology division of the Cecil H. and Ida Green Comprehensive Center for Molecular, Computational and Systems Biology at UT Southwestern. "Even though each cell may have the same set of genes turned on - the same hard-wired genetic circuit - there will still be slight variations in the amount of the various proteins those genes produce, some fluctuation in the amount of each circuit component. No two cells are alike in terms of their chemical composition."
Conventional scientific thinking has been that the random nature of such fluctuations within cells interferes with the reliable operation of biological systems. However, Dr. Süel's research team hypothesized that noise in one particular genetic circuit might be beneficial, linked to a process that controls cell fate.
To determine the biological role for noise, the researchers analyzed a genetic circuit that controls the transformation of bacteria cells from one state to another. This process, called differentiation, is akin to that used by human stem cells to change into a specific tissue type.
In a series of theoretical calculations and actual experiments, the researchers found that the particular circuit they investigated appears to have evolved in this bacterium to amplify cellular noise. Dr. Süel and his colleagues determined that by dampening the noise level within the bacterial cells, they could prevent the cells' transformation between states, essentially "tuning" cellular behavior.
"The amplitude of cellular noise correlates with the probability of triggering differentiation," Dr. Süel said. "This is experimental evidence that a genetic circuit utilizes noise to drive a biological process."
Typically, scientists examine genes and proteins individually to try to determine their functions within a cell. However, Dr. Süel said that's like examining each capacitor or switch in an electrical circuit in an attempt to understand the function of the electrical device in which the circuit is housed.
"Our research provides a systems-level view of how gene circuits work as a whole," he said.
Dr. Süel said the next step in his research would be to uncover the theoretical design principles of genetic circuits and what role interactions between distinct circuits play in regulating complex biological processes, such the differentiation of multipotent stem cells.
Dr. Süel, who earned his doctorate in molecular biophysics from UT Southwestern, carried out much of the work for the Science paper while a postdoctoral research fellow at the California Institute of Technology. He joined the UT Southwestern faculty in November and is an Endowed Scholar in Biomedical Research.
Other co-authors on the Science paper are Rajan Kulkarni and senior author Michael Elowitz, both of Caltech; Jonathan Dworkin of Columbia University; and Jordi Garcia-Ojalvo of the Universitat Politecnica de Catalunya in Spain.
The work was funded in part by the National Institutes of Health, the Searle Scholars Program and the Human Frontier Science Program.
UT Southwestern Medical Center
"Noise in biological systems is a fact of life," said Dr. Süel, a member of the systems biology division of the Cecil H. and Ida Green Comprehensive Center for Molecular, Computational and Systems Biology at UT Southwestern. "Even though each cell may have the same set of genes turned on - the same hard-wired genetic circuit - there will still be slight variations in the amount of the various proteins those genes produce, some fluctuation in the amount of each circuit component. No two cells are alike in terms of their chemical composition."
Conventional scientific thinking has been that the random nature of such fluctuations within cells interferes with the reliable operation of biological systems. However, Dr. Süel's research team hypothesized that noise in one particular genetic circuit might be beneficial, linked to a process that controls cell fate.
To determine the biological role for noise, the researchers analyzed a genetic circuit that controls the transformation of bacteria cells from one state to another. This process, called differentiation, is akin to that used by human stem cells to change into a specific tissue type.
In a series of theoretical calculations and actual experiments, the researchers found that the particular circuit they investigated appears to have evolved in this bacterium to amplify cellular noise. Dr. Süel and his colleagues determined that by dampening the noise level within the bacterial cells, they could prevent the cells' transformation between states, essentially "tuning" cellular behavior.
"The amplitude of cellular noise correlates with the probability of triggering differentiation," Dr. Süel said. "This is experimental evidence that a genetic circuit utilizes noise to drive a biological process."
Typically, scientists examine genes and proteins individually to try to determine their functions within a cell. However, Dr. Süel said that's like examining each capacitor or switch in an electrical circuit in an attempt to understand the function of the electrical device in which the circuit is housed.
"Our research provides a systems-level view of how gene circuits work as a whole," he said.
Dr. Süel said the next step in his research would be to uncover the theoretical design principles of genetic circuits and what role interactions between distinct circuits play in regulating complex biological processes, such the differentiation of multipotent stem cells.
Dr. Süel, who earned his doctorate in molecular biophysics from UT Southwestern, carried out much of the work for the Science paper while a postdoctoral research fellow at the California Institute of Technology. He joined the UT Southwestern faculty in November and is an Endowed Scholar in Biomedical Research.
Other co-authors on the Science paper are Rajan Kulkarni and senior author Michael Elowitz, both of Caltech; Jonathan Dworkin of Columbia University; and Jordi Garcia-Ojalvo of the Universitat Politecnica de Catalunya in Spain.
The work was funded in part by the National Institutes of Health, the Searle Scholars Program and the Human Frontier Science Program.
UT Southwestern Medical Center
Scientists find potential 'off-switch' for HIV virus
While there is no cure for lingering viral infections such as HIV and herpes, a recent study at Princeton University suggests it may be possible to deactivate such viruses indefinitely with the flick of a genetic switch.
More Genetic Circuit Current Events and Genetic Circuit News Articles
 |
Evolutionary Electronics: Automatic Design of Electronic Circuits and Systems by Genetic Algorithms (International Series on Computational Intelligence) by Ricardo Salem Zebulum (Author), Marco Aurelio Pacheco (Author), Marley Maria Be Vellasco (Author) From the explosion of interest, research, and applications of evolutionary computation a new field emerges-evolutionary electronics. Focused on applying evolutionary computation concepts and techniques to the domain of electronics, many researchers now see it as holding the greatest potential for overcoming the drawbacks of conventional design techniques.Evolutionary Electronics: Automatic Design of Electronic Circuits and Systems by Genetic Algorithms formally introduces and defines this area of research, presents its main challenges in electronic design, and explores emerging technologies. It describes the evolutionary computation paradigm and its primary algorithms, and explores topics of current interest, such as multi-objective optimization. The authors examine numerous evolutionary... |
 |
Engineering Genetic Circuits (Chapman & Hall/Crc Mathematical and Computational Biology) by Chris J. Myers (Author) An Introduction to Systems Bioengineering Focusing on genetic regulatory networks, Engineering Genetic Circuits presents the modeling, analysis, and design methods for systems biology. It discusses how to examine experimental data to learn about mathematical models, develop efficient abstraction and simulation methods to analyze these models, and use analytical methods to guide the design of new circuits. After reviewing the basic molecular biology and biochemistry principles needed to understand genetic circuits, the book describes modern experimental techniques and methods for discovering genetic circuit models from the data generated by experiments. The next four chapters present... |
 |
Genetic Dissection of Neural Circuits and Behavior, Volume 65 (Advances in Genetics) by Stephen F. Goodwin (Editor) Genes interact with environment, experience, and the biology of the brain to shape an animal's behavior. This latest volume in Advances in Genetics, organized according to the most widely used model organisms, describes the latest genetic discoveries in relation to neural circuit development and activity. * Explores latest topics in neural circuits and behavior research in zebrafish, drosophila, c.elegans, and mouse models * Includes methods for testing with ethical, legal, and social implications * Critically analyzes prospects future prospects |
|
Workers are entitled to genetic privacy at work, Ninth Circuit holds.: An article from: Trial by Julie Gannon Shoop (Author) This digital document is an article from Trial, published by Association of Trial Lawyers of America on May 1, 1998. The length of the article is 779 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. From the supplier: The United States Court of Appeals for the 9th Circuit ruled in the 1998 case of Norman-Bloodsaw v. Lawrence Berkeley Laboratory that an employer could not test employees for highly private genetic information without the workers' consent, for this would be unconstitutional invasion of privacy and, in some cases, job discrimination in violation of Title VII. The court ventured with this case... | |
|
Environmental policy in the age of genetics.: An article from: Issues in Science and Technology by Wendy Yap (Author), David Rejeski (Author) This digital document is an article from Issues in Science and Technology, published by National Academy of Sciences on September 22, 1998. The length of the article is 2393 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. From the supplier: The emergence of gene chip technology is expected to cause a radical shift in environmental regulations that safeguard human health. While the gene chip promises to bring new opportunities for prevention and early intervention and allow policymakers to custom-design strategies to minimize human exposure to environmental threats at a molecular level, its potential... | |
![A hybrid model by clustering and evolving fuzzy rules for sales decision supports in printed circuit board industry [An article from: Decision Support Systems]](http://ecx.images-amazon.com/images/I/5143C7T64DL._SL160_.jpg) |
A hybrid model by clustering and evolving fuzzy rules for sales decision supports in printed circuit board industry [An article from: Decision Support Systems] by P.C. Chang (Author), C.H. Liu (Author), Y.W. Wang (Author) This digital document is a journal article from Decision Support Systems, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: This research develops a hybrid model by integrating Self Organization Map (SOM) neural network, Genetic Algorithms (GA) and Fuzzy Rule Base (FRB) to forecast the future sales of a printed circuit board factory. This hybrid model encompasses two novel concepts: (1) clustering an FRB into different clusters, thus the interaction between fuzzy rules is reduced and a more accurate prediction model can be established, and (2) evolving an FRB by optimizing the number of fuzzy terms of the input and output... |
![Heuristic approaches for batching jobs in printed circuit board assembly [An article from: Computers and Operations Research]](http://ecx.images-amazon.com/images/I/41SS7GZHX6L._SL160_.jpg) |
Heuristic approaches for batching jobs in printed circuit board assembly [An article from: Computers and Operations Research] by S.K. Williams (Author), M.J. Magazine (Author) This digital document is a journal article from Computers and Operations Research, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: The goal of the printed circuit board job-batching problem is to minimize the total manufacturing time required to process a set of printed circuit board jobs on an insertion machine. We have developed four families of heuristics to solve this problem: the clustering family, the bin-packing family, a family of sequencing genetic algorithms, and a grouping genetic algorithm. Within each family of heuristics, we developed several variations. Some of the variations use techniques from the literature and... |
 |
Variation-Aware Analog Structural Synthesis: A Computational Intelligence Approach (Analog Circuits and Signal Processing) by Trent McConaghy (Author), Pieter Palmers (Author), Peng Gao (Author), Michiel Steyaert (Author), Georges Gielen (Author) Variation-Aware Analog Structural Synthesis describes computational intelligence-based tools for robust design of analog circuits. It starts with global variation-aware sizing and knowledge extraction, and progressively extends to variation-aware topology design. The computational intelligence techniques developed in this book generalize beyond analog CAD, to domains such as robotics, financial engineering, automotive design, and more. |
 |
Genetic Algorithms for VLSI Design, Layout and Test Automation by Pinaki Mazumder (Author), Elizabeth Rudnick (Author) This book provides details about some of the EDA applications where GAs have been used. These applications include partitioning, automatic placement and routing, technology mapping for FPGAs, automatic test generation, and power estimation. One chapter is devoted to each of these topics. The objective is to provide examples where GAs have been successfull applied in the past so that the reader will be able to apply similar techniques in solving his/her own problems. |
 |
Evolvable Hardware (Genetic and Evolutionary Computation) by Tetsuya Higuchi (Editor), Yong Liu (Editor), Xin Yao (Editor) Evolvable hardware (EHW) refers to hardware whose architecture/structure and functions change dynamically and autonomously in order to improve its performance in carrying out tasks. The emergence of this field has been profoundly influenced by the progress in reconfigurable hardware and evolutionary computation. Traditional hardware can be inflexible—the structure and its functions are often impossible to change once it is created. However, most real world problems are not fixed—they change with time. In order to deal with these problems efficiently and effectively, different hardware structures are necessary. EHW provides an ideal approach to make hardware "soft" by adapting the structure to a problem dynamically. The contributions in this book provide the basics... |
| © 2009 BrightSurf.com |