Researchers Gain Insights Into 'On-Off' Switch for Cells
|
TOOLBOX
   Resize
COMMENT
 Discussion Policy
 CLOSE
Comments that include profanity or personal attacks or other inappropriate comments or material will be removed from the site. Additionally, entries that are unsigned or contain "signatures" by someone other than the actual author will be removed. Finally, we will take steps to block users who violate any of our posting standards, terms of use or privacy policies or any other policies governing this site. Please review the full rules governing commentaries and discussions. You are fully responsible for the content that you post.
Who's Blogging  |
MONDAY, March 24 (HealthDay News) -- New insights about an on-off switch that controls cell growth could one day help identify targets for drugs to treat cancer and other diseases that involve unnatural cell growth, researchers are reporting.
The researchers at the Duke Institute for Genome Sciences and Policy found that if the switch is "on," then a cell will divide, even if it's damaged or the signal to grow disappears.
The on-off switch is part of the pathway that controls cell division, the process that creates new cells. Before a cell divides, it goes through a checklist to make sure everything is in order. If the cell senses a problem early on, it can halt the process. But once the cell passes what's called the restriction point, it can no longer stop division. This on-off switch controls the restriction point and therefore plays an important role in cell growth, according to the study.
The on-off switch is part of the Rb-E2F signaling pathway. Rb (retinoblastoma) is an important tumor suppressor gene, and E2F is a transcription factor that governs the expression of all the genes important for cell growth, the researchers explained.
This pathway is found in all multi-cellular life forms, from humans to plants. The pathway is triggered when a cell receives an external chemical signal to grow.
"The wiring diagram is fundamentally the same. It's very likely that different organisms have evolved a very conserved design principle to regulate their growth," study lead author Guang Yao, a postdoctoral fellow in Duke's department of molecular genetics and microbiology, said in a prepared statement.
In their study, Yao and colleagues also found that the switch is bistable -- once it's turned on by an external signal, it can stay turned on, even if the signal vanishes.
The study results are published in the April issue of the journalNature Cell Biology.
More information
The Biology Project at the University of Arizona has more about cells.
SOURCE: Duke University, news release, March 23, 2008
![[slate.com logo]](http://media.washingtonpost.com/wp-dyn/content/graphic/2007/09/27/GR2007092701096.GIF)
