Brain Regions Implicated in Mental Disorders Influenced by Neanderthal Genes

NIMH researchers have produced the first direct evidence that parts of our brains implicated in mental disorders may be shaped by a “residual echo” from our ancient past. The more a person’s genome carries genetic vestiges of Neanderthals, the more certain parts of his or her brain and skull resemble those of humans’ evolutionary cousins that went extinct 40,000 years ago, says NIMH’s Karen Berman, M.D.

In particular, the parts of our brains that enable us to use tools and visualize and locate objects owe some of their lineage to Neanderthal-derived gene variants that are part of our genomes and affect the shape of those structures – to the extent that an individual harbors the ancient variants. But this may involve trade-offs with our social brain. The evidence from MRI scans suggests that such Neanderthal-derived genetic variation may affect the way our brains work today – and may hold clues to understanding deficits seen in schizophrenia and autism-related disorders, say the researchers.

Berman, Michael Gregory, M.D., of the NIMH Section on Integrative Neuroimaging, and colleagues, report on their magnetic resonance imaging (MRI) study online July 24, 2017, in the journal Scientific Reports. 

During their primordial migration out of Africa, ancestors of present-day humans are thought to have interbred with Neanderthals, whose brain characteristics can be inferred from their fossilized skulls. For example, these indicate that Neanderthals had more prominent visual systems than modern humans. 

“It’s been proposed that Neanderthals depended on visual-spatial abilities and toolmaking, for survival, more so than on the social affiliation and group activities that typify the success of modern humans – and that Neanderthal brains evolved to preferentially support these visuospatial functions,” Berman explained. “Now we have direct neuroimaging evidence that such trade-offs may still be operative in our brains.”

Might some of us, more than others, harbor Neanderthal-derived gene variants that may bias our brains toward trading sociability for visuospatial prowess – or vice versa? The new study adds support to this possibility by showing how these gene variants influence the structure of brain regions underlying those abilities.

To test this possibility, Gregory and Berman measured the amount of Neanderthal variants in a sample of 221 participants of European ancestry drawn from the NIMH Sibling Study of schizophrenia risk and related it to MRI measures of brain structure.

The new MRI evidence points to a shared gene variant that is likely involved in development of the brain’s visual system. Similarly, Neanderthal variants impacting development of a particular suspect brain area may help to inform cognitive disability seen in certain brain disorders, say the researchers.

For example, in 2012, Berman and colleagues reported on how genetic variation shapes the structure and function of a brain area called the Insula in the autism-related disorder Williams Syndrome . People with this rare genetic disorder are overly sociable and visuo-spatially impaired – conspicuously opposite to the hypothesized Neanderthal propensities and more typical cases on the autism spectrum.  Mice in which a gene affected by Williams syndrome is experimentally deleted  show increased separation anxiety. And just last week, researchers showed  that the same genetic variability also appears to explain why dogs are friendlier than wolves .

Berman and Gregory’s team is currently working on further studies documenting the pivotal role of this suspect genetic variation in shaping the insula and related social brain circuitry.

This article has been republished from materials provided by NIH. Note: material may have been edited for length and content. For further information, please contact the cited source.

Reference 

Gregory, M. D., Kippenhan, J. S., Eisenberg, D. P., Kohn, P. D., Dickinson, D., Mattay, V. S., . . . Berman, K. F. (2017). Neanderthal-Derived Genetic Variation Shapes Modern Human Cranium and Brain. Scientific Reports, 7(1). doi:10.1038/s41598-017-06587-0