Striatal Dopamine Gene Network Moderates the Effect of Early Adversity on the Risk for Adult Psychiatric and Cardiometabolic Comorbidity

Barbara Barth,Danusa Mar Arcego,Euclides Jose de Mendonca Filho,Randriely Merscher Sobreira de Lima,Carine Parent,Carla Dalmaz,Andre Krumel Portella,Irina Pokhvisneva,Michael J. Meaney,Patricia Pelufo Silveira

SCIENTIFIC REPORTS（2024）

McGill Univ | Universidade Federal do Rio Grande do Sul

Cited 1|Views0

Abstract

Cardiometabolic and psychiatric disorders often co-exist and share common early life risk factors, such as low birth weight. However, the biological pathways linking early adversity to adult cardiometabolic/psychiatric comorbidity remain unknown. Dopamine (DA) neurotransmission in the striatum is sensitive to early adversity and influences the development of both cardiometabolic and psychiatric diseases. Here we show that a co-expression based polygenic score (ePGS) reflecting individual variations in the expression of the striatal dopamine transporter gene (SLC6A3) network significantly interacts with birth weight to predict psychiatric and cardiometabolic comorbidities in both adults (UK Biobank, N = 225,972) and adolescents (ALSPAC, N = 1188). Decreased birth weight is associated with an increased risk for psychiatric and cardiometabolic comorbidities, but the effect is dependent on a striatal SLC6A3 ePGS, that reflects individual variation in gene expression of genes coexpressed with the SLC6A3 gene in the striatum. Neuroanatomical analyses revealed that SNPs from the striatum SLC6A3 ePGS were significantly associated with prefrontal cortex gray matter density, suggesting a neuroanatomical basis for the link between early adversity and psychiatric and cardiometabolic comorbidity. Our study reveals that psychiatric and cardiometabolic diseases share common developmental pathways and underlying neurobiological mechanisms that includes dopamine signaling in the striatum.

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