Gene regulation in humans is closer than expected to simple organisms

Gene networks are some of the most basic features of a living organism. An external or internal stimulus activates some genes, which in turn control others genes whose activity turns on or off various biological processes (such as the cell cycle, energy production, DNA repair, cellular suicide etc).

Many of the regulatory functions are controlled by attachment of special proteins (transcription factors) to 6 - 10 nucleotide long binding sequences located on the DNA, activating or suppressing expression of the regulated gene. Our ability to identify these binding sites is essential to understand the way biological networks operate.

As the genomes of various organisms became known, it turned out that complex and simple organisms differ less than anticipated in the sizes and makeup of their genomes; complexity of an organism is now believed to be reflected mainly in the manner in which expression is regulated. According to consensus, transcription of human genes is regulated predominantly by factors that bind to sites whose distances from the transcription start site may vary widely and reach tens of thousands of base pairs.

To test the validity of this belief/consensus, researchers from the Weizmann Institute of Science in Israel have performed a genome-wide study of functional human transcription factor binding sites that encompasses nearly ten thousand genes and four hundred known binding motifs. Using a novel method that was developed to identify reliably functional binding motifs, they discovered that in human (and mouse) a surprisingly large fraction of the functional binding sites was concentrated very close to the transcription start site. Hence on the basis of currently available data it seems that the most basic underlying principles and strategies used by the genomes of higher organisms to regulate gene expression are quite close to those used by simple organisms like bacteria and yeast.

The discovery and the method will allow more focused and reliable search for transcriptional binding sites and hence may turn into a major tool to be used in the quest for the transcriptional networks whose function governs all cellular processes, and whose breakdown causes complex diseases. It will generate progress in establishing the design principles used by the transcription process in high organism, and allow a more focused search for the origins of their complexity.

Source: Public Library of Science

Wealth of genomic hotspots discovered in embryonic stem cells
In a paper published in Cell on June 13, 2008, Singapore scientists at the Genome Institute of Singapore (GIS) and the National University of Singapore (NUS) unveil an atlas that showing the location of "genomic hotspots" of essential protein "switches" (transcription factors) that are critical for maintaining the embryonic stem (ES) cell state.
How defects in 1 gene cause 3 distinct and devastating human diseases
By studying heat-loving microbes, two research teams have gained new insight into how seemingly small differences in a single protein involved in DNA transcription and repair can lead to strikingly different genetic disorders in humans.
Genome analysis reveals new protein associated with breast cancer progression
A novel systems-based approach that combines comprehensive gene expression profiling with genome-wide transcription factor analysis and protein-protein interaction has led researchers to an important genetic marker that can help physicians know which breast cancer patients are at highest risk and will require more aggressive treatment, a research team based at the University of Chicago Medical Center reports in the April 15, 2008, issue of the journal Molecular Systems Biology.
Molecular alliance that sustains embryonic stem cell state
One of the four ingredients in the genetic recipe that scientists in Japan and the U.S. followed last year to persuade human skin cells to revert to an embryonic stem cell state, is dispensable in ES cells, thanks to the presence of a molecular alliance between a specific group of key proteins known as transcription factors, a research team led by the Genome Institute of Singapore (GIS) under the Agency for Science, Technology and Research (A*STAR) reports in the current issue of Nature Cell Biology.
Gene regulators bind promiscuously, but often do nothing
Biologists are developing ever more sophisticated means to characterize molecular interactions in living systems. But a new study suggests that many of the interactions detected by a widely-used experimental method are functionally irrelevant.
Evolution is driven by gene regulation
It is not just what’s in your genes, it’s how you turn them on that accounts for the difference between species — at least in yeast — according to a report by Yale researchers in this week’s issue of Science.
Study identifies new gene therapy tools for inherited blindness
An improved approach to gene therapy may one day treat some of the nearly 200 inherited forms of blindness, scientists at Washington University School of Medicine in St. Louis suggest this week.
Mice and men make livers differently
Scientists often study mice as a model for human biology and disease, because their basic biological processes are assumed to be essentially the same as those of humans.

Gene regulation in humans is closer than expected to simple organisms

Related stories:

News discussion: