Tuesday, September 18, 2012

Roles of novel epigenetic chemical in the brain illuminated

ScienceDaily (Sep. 14, 2012) ? Researchers from the Centre for Addiction and Mental Health (CAMH) have identified a new role of a chemical involved in controlling the genes underlying memory and learning.

"The brain is a plastic tissue, and we know that learning and memory require various genes to be expressed," says CAMH Senior Scientist Dr. Art Petronis, who is a senior author on the new study. "Our research has identified how the chemical 5-hmC may be involved in the epigenetic processes allowing this plasticity." Dr. Petronis is head of the Krembil Family Epigenetics Laboratory in CAMH's Campbell Family Mental Health Research Institute.

5-hmC is an epigenetic modification of DNA, and was discovered in humans and mice in 2009. DNA modifications are chemical changes to DNA. They flag genes to be turned "on" -- signalling the genome to make a protein -- or turned "off." As the overwhelming majority of cells in an individual contain the same genetic code, this pattern of flags is what allows a neuron to use the same genome as a blood or liver cell, but create a completely different and specialized cellular environment.

The research, published online in Nature Structural & Molecular Biology, sheds light on the role of 5-hmC. Intriguingly, it is more abundant in the brain than in other tissues in the body, for reasons not clear to date.

The CAMH team of scientists examined DNA from a variety of tissues, including the mouse and human brain, and looked at where 5-hmC was found in the genome. They detected that 5-hmC had a unique distribution in the brain: it was highly enriched in genes related to the synapse, the dynamic tips of brain cells. Growth and change in the synapse allow different brain cells to "wire" together, which allows learning and memory.

"This enrichment of 5-hmC in synapse-related genes suggests a role for this epigenetic modification in learning and memory," says Dr. Petronis.

The team further showed that 5-hmC had a special distribution even within the gene. The code for one gene can be edited and "spliced" to create several different proteins. Dr. Petronis found that 5-hmC is located at "splice junctions," the points where the gene is cut before splicing.

"5-hmC may signal the cell's splicing machinery to generate the diverse proteins that, in turn, give rise to the unprecedented complexity of the brain," he says.

The research team is continuing to investigate the role of 5-hmC in more detail, and to determine whether 5-hmC function is different in people with bipolar disorder and schizophrenia compared to people without these diagnoses.

This research was funded by the U.S National Institutes of Health, the Canadian Institutes of Health Research, and the Tapscott Chair in Schizophrenia Studies at the University of Toronto.

The Centre for Addiction and Mental Health (CAMH) is Canada's largest mental health and addiction teaching hospital, as well as one of the world's leading research centres in the area of addiction and mental health. CAMH combines clinical care, research, education, policy development and health promotion to help transform the lives of people affected by mental health and addiction issues.

CAMH is fully affiliated with the University of Toronto, and is a Pan American Health Organization/World Health Organization Collaborating Centre.

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The above story is reprinted from materials provided by Centre for Addiction and Mental Health.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.


Journal Reference:

  1. Tarang Khare, Shraddha Pai, Karolis Koncevicius, Mrinal Pal, Edita Kriukiene, Zita Liutkeviciute, Manuel Irimia, Peixin Jia, Carolyn Ptak, Menghang Xia, Raymond Tice, Mamoru Tochigi, Solange Mor?ra, Anaies Nazarians, Denise Belsham, Albert H C Wong, Benjamin J Blencowe, Sun Chong Wang, Philipp Kapranov, Rafal Kustra, Viviane Labrie, Saulius Klimasauskas, Arturas Petronis. 5-hmC in the brain is abundant in synaptic genes and shows differences at the exon-intron boundary. Nature Structural & Molecular Biology, 2012; DOI: 10.1038/nsmb.2372

Note: If no author is given, the source is cited instead.

Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of ScienceDaily or its staff.

Source: http://feeds.sciencedaily.com/~r/sciencedaily/mind_brain/mental_health/~3/ry5hIZdIW94/120917123854.htm

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