Recent News \| Archives \| Tags \| About \| Newsletter \| Submit News \| Links \| Subscribe

New Articles

Structure of key epigenetics component identified 9/5/2008

DNA editing tool flips its target 9/4/2008

Virus weaves itself into the DNA transferred from parents to babies 9/3/2008

The first autism disease genes 9/2/2008

Location, Location, Location Important For Genes, Too 9/1/2008

Explaining a genetic disorder's unique shift 8/31/2008

Nonviable Seeds May Contain Research-Quality DNA 8/29/2008

First gene associated with dry macular degeneration found 8/28/2008

DNA Barcodes: Are They Always Accurate? 8/27/2008

Largest study of its kind implicates gene abnormalities in bipolar disorder 8/25/2008

Genes may make some people more prone to anxiety 8/24/2008

Team finds clue in basic biology of X-linked mental retardation 8/22/2008

Genome of saltwater creature could aid understanding of gene grouping 8/21/2008

Researchers discover technology that silences genes 8/20/2008

Analysis of Lake Washington microbes shows the power of metagenomic approaches 8/20/2008

Lab characterizes gene essential for prenatal development of nervous system (2/3/2008)

Tags:
nervous system, embryonic development, stem cells, neurons

The Stowers Institute's Trainor Lab has demonstrated the role of a gene important to the embryonic development of the nervous system, a process that requires coordination of differentiation of immature neural cells with the cycle of cell division that increases their numbers. Until now, the mechanisms regulating these distinct cellular activities have been poorly understood. The findings will be published in the Feb. 15 issue of Development.

In this work, the team used gain- and loss-of-function mutations in mice to isolate novel roles for the mouse Cux2 gene in regulating neurogenesis. They established that Cux2 directs neuroblast development, neuronal differentiation, and cell-fate determination in the spinal cord by coupling progression through the cycle of cell division with differentiation of neural cells by direct activation of two key neurogenic determinants, Neurod and p27Kipl.

"We were excited to uncover, for the first time, multiple functional roles for a Cux-like homeodomain transcription factor in regulating key aspects of spinal cord neurogenesis," said Angelo Iulianella, Ph.D., Senior Research Associate and first author on the publication. "The demonstration that Cux2 integrates cell-cycle progression with neural progenitor differentiation and cell-fate determination provides a much clearer picture of the complex process of neurogenesis."

"The impact of cell cycle length on the formation of interneurons versus motoneurons was a surprising finding," said Paul Trainor, Ph.D., Associate Investigator, and senior author on the publication. "Ongoing work involves global proteomic analyses aimed at identifying the complete set of Cux2-interacting partners. We believe these efforts will be essential to understanding how Cux2 elicits its multiple functions during neurogenesis."

Further analysis of Cux2 will make it possible to extend these findings not only to spinal cord development, but also to the mammalian cortex, where Cux genes demarcate specific upper layers of cortical neurons and may have played a role in the expansion and increased complexity of the cortex during evolution.

Note: This story has been adapted from a news release issued by the Stowers Institute for Medical Research

Post Comments:

Search

Archives \| Submit News \| Advertise With Us \| Contact Us \| Links