Structural Brain Connectivity as a Genetic Marker for Schizophrenia

Publication date

2016-01-01

Authors

Bohlken, Marc M.
Brouwer, Rachel M.ISNI 0000000389353779
Mandl, René C WISNI 0000000388301774
Van Den Heuvel, Martijn P.ISNI 0000000391123921
Hedman, Anna M.
De Hert, Marc
Cahn, WiepkeISNI 0000000368964140
Kahn, René S.ISNI 0000000035067353
Hulshoff Pol, Hilleke E.ORCID 0000-0002-2038-5281ISNI 000000035942330X

Editors

Advisors

Supervisors

Document Type

Article

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License

taverne

Abstract

IMPORTANCE: Schizophrenia is accompanied by a loss of integrity of white matter connections that compose the structural brain network, which is believed to diminish the efficiency of information transfer among brain regions. However, it is unclear to what extent these abnormalities are influenced by the genetic liability for developing the disease. OBJECTIVE: To determine whether white matter integrity is associated with the genetic liability for developing schizophrenia. DESIGN, SETTING, AND PARTICIPANTS: In 70 individual twins discordant for schizophrenia and 130 matched individual healthy control twins, structural equation modeling was applied to quantify unique contributions of genetic and environmental factors on brain connectivity and disease liability. The data for this study were collected from October 1, 2008, to September 30, 2013. The data analysis was performed between November 1, 2013, and March 30, 2015. MAIN OUTCOME MEASURES: Structural connectivity and network efficiency were assessed through diffusion-weighted imaging, measuring fractional anisotropy (FA) and streamlines. RESULTS: The sample included 30 monozygotic twins matched to 72 control participants and 40 dizygotic twins matched to 58 control participants. Lower global FA was significantly correlated with increased schizophrenia liability (phenotypic correlation, -0.25; 95% CI, -0.38 to -0.10; P = .001), with 83.4% explained by common genes. In total, 8.1% of genetic variation in global FA was shared with genetic variance in schizophrenia liability. Local reductions in network connectivity (as defined by FA-weighted local efficiency) of frontal, striatal, and thalamic regions encompassed 85.7% of genetically affected areas. Multivariate genetic modeling revealed that global FA contributed independently of other genetic markers, such as white matter volume and cortical thickness, to schizophrenia liability. CONCLUSIONS AND RELEVANCE: Global reductions in white matter integrity in schizophrenia are largely explained by the genetic risk of developing the disease. Network analysis revealed that genetic liability for schizophrenia is primarily associated with reductions in connectivity of frontal and subcortical regions, indicating a loss of integrity along the white matter fibers in these regions. The reported reductions in white matter integrity likely represent a separate and novel genetic vulnerability marker for schizophrenia.

Keywords

Taverne, Psychiatry and Mental health, Journal Article, Research Support, Non-U.S. Gov't, Twin Study

Citation

Bohlken, M M, Brouwer, R M, Mandl, R C W, Van Den Heuvel, M P, Hedman, A M, De Hert, M, Cahn, W, Kahn, R S & Hulshoffpol, H 2016, 'Structural Brain Connectivity as a Genetic Marker for Schizophrenia', JAMA Psychiatry, vol. 73, no. 1, pp. 11-19. https://doi.org/10.1001/jamapsychiatry.2015.1925