You may think your brother-in-law has sawdust for brains. But in fact, researchers say human brains -- yes, even the one that bounces around inside the head of your least favorite politician -- are all pretty much the same.
Or to put it more scientifically, the human brain shows a "consistent molecular architecture." The finding is from a pair of studies supported by the National Institutes of Health that have created databases revealing when and where genes turn on and off in multiple brain regions through development.
"Our study shows how 650,000 common genetic variations that make each of us a unique person may influence the ebb and flow of 24,000 genes in the most distinctly human part of our brain as we grow and age," explained Joel Kleinman, M.D., Ph.D., of the National Institute of Mental Health (NIMH) Clinical Brain Disorders Branch.
Kleinman and NIMH grantee Nenad Sestan, M.D., Ph.D. of Yale University, New Haven, Conn., led the sister studies in the Oct. 27, 2011 issue of the journal Nature.
 |
| Our brains are all made of the same stuff. Despite individual and ethnic genetic diversity, our prefrontal cortex shows a consistent molecular architecture. For example, overall differences in the genetic code (“genetic distance”) between African -Americans (AA) and caucasians (cauc) showed no effect on their overall difference in expressed transcripts (“transcriptional distance”) |
New hope
"Having at our fingertips detailed information about when and where specific gene products are expressed in the brain brings new hope for understanding how this process can go awry in schizophrenia, autism and other brain disorders," said NIMH Director Thomas R. Insel, M.D.
Both studies found that rapid gene expression during fetal development abruptly switches to much slower rates after birth that gradually decline and eventually level off in middle age. These rates surge again as the brain ages in the last decades, mirroring rates seen in childhood and adolescence, according to one of the studies.
The databases hold secrets to how the brain’s ever-changing messenger chemical systems, cells and development processes are related to gene expression patterns through development.
For example, if a particular version of a gene is implicated in a disorder, the new resources might reveal how that variation affects the gene’s expression over time and by brain region. By identifying even distant genes that may be turning on and off in-sync, the databases may help researchers discover whole modules of genes involved in the illness. They can also reveal how variation in one gene influences another's expression.
