@article {NadigENEURO.0265-18.2018, author = {Ajay Nadig and Paul K. Reardon and Jakob Seidlitz and Cassidy L. McDermott and Jonathan D. Blumenthal and Liv S. Clasen and Francois Lalonde and Jason P. Lerch and M. Mallar Chakravarty and Armin Raznahan}, title = {Carriage of Supernumerary Sex Chromosomes Decreases the Volume and Alters the Shape of Limbic Structures}, volume = {5}, number = {5}, elocation-id = {ENEURO.0265-18.2018}, year = {2018}, doi = {10.1523/ENEURO.0265-18.2018}, publisher = {Society for Neuroscience}, abstract = {Sex chromosome aneuploidy (SCA) increases risk for several psychiatric disorders associated with the limbic system, including mood and autism spectrum disorders. Thus, SCA offers a genetics-first model for understanding the biological basis of psychopathology. Additionally, the sex-biased prevalence of many psychiatric disorders could potentially reflect sex chromosome dosage effects on brain development. To clarify how limbic anatomy varies across sex and sex chromosome complement, we characterized amygdala and hippocampus structure in a uniquely large sample of patients carrying supernumerary sex chromosomes (n = 132) and typically developing controls (n = 166). After adjustment for sex-differences in brain size, karyotypically normal males (XY) and females (XX) did not differ in volume or shape of either structure. In contrast, all SCAs were associated with lowered amygdala volume relative to gonadally-matched controls. This effect was robust to three different methods for total brain volume adjustment, including an allometric analysis that derived normative scaling rules for these structures in a separate, typically developing population (n = 79). Hippocampal volume was insensitive to SCA after adjustment for total brain volume. However, surface-based analysis revealed that SCA, regardless of specific karyotype, was consistently associated with a spatially specific pattern of shape change in both amygdala and hippocampus. In particular, SCA was accompanied by contraction around the basomedial nucleus of the amygdala and an area crossing the hippocampal tail. These results demonstrate the power of SCA as a model to understand how copy number variation can precipitate changes in brain systems relevant to psychiatric disease.}, URL = {https://www.eneuro.org/content/5/5/ENEURO.0265-18.2018}, eprint = {https://www.eneuro.org/content/5/5/ENEURO.0265-18.2018.full.pdf}, journal = {eNeuro} }