Chronic pharmacologic manipulation of dopamine transmission ameliorates metabolic disturbance in Trappc9-linked brain developmental syndrome
Yan Li, Muhammad Usman, Ellen Sapp, Yuting Ke, Zejian Wang, Adel Boudi, Marian DiFiglia, Xueyi Li
Yan Li, Muhammad Usman, Ellen Sapp, Yuting Ke, Zejian Wang, Adel Boudi, Marian DiFiglia, Xueyi Li
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Research Article Metabolism Neuroscience

Chronic pharmacologic manipulation of dopamine transmission ameliorates metabolic disturbance in Trappc9-linked brain developmental syndrome

Abstract

Loss-of-function mutations of the gene encoding the trafficking protein particle complex subunit 9 (Trappc9) cause autosomal recessive intellectual disability and obesity by unknown mechanisms. Genome-wide analysis links Trappc9 to nonalcoholic fatty liver disease (NAFLD). Trappc9-deficient mice have been shown to appear overweight shortly after weaning. Here, we analyzed serum biochemistry and histology of adipose and liver tissues to determine the incidence of obesity and NAFLD in Trappc9-deficient mice and combined transcriptomic and proteomic analyses, pharmacological studies, and biochemical and histological examinations of postmortem mouse brains to unveil mechanisms involved. We found that Trappc9-deficient mice presented with systemic glucose homeostatic disturbance, obesity, and NAFLD, which were relieved upon chronic treatment combining dopamine receptor D2 (DRD2) agonist quinpirole and DRD1 antagonist SCH23390. Blood glucose homeostasis in Trappc9-deficient mice was restored upon administering quinpirole alone. RNA-sequencing analysis of DRD2-containing neurons and proteomic study of brain synaptosomes revealed signs of impaired neurotransmitter secretion in Trappc9-deficient mice. Biochemical and histological studies of mouse brains showed that Trappc9-deficient mice synthesized dopamine normally, but their dopamine-secreting neurons had a lower abundance of structures for releasing dopamine in the striatum. Our study suggests that Trappc9 loss of function causes obesity and NAFLD by constraining dopamine synapse formation.

Authors

Yan Li, Muhammad Usman, Ellen Sapp, Yuting Ke, Zejian Wang, Adel Boudi, Marian DiFiglia, Xueyi Li

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Figure 5

Trappc9 deficiency disrupts systemic glucose homeostasis by abating DRD2 stimulation without affecting dopamine synthesis in the brain.

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Trappc9 deficiency disrupts systemic glucose homeostasis by abating DRD2...
Comparisons of blood glucose levels in WT and Trappc9-KO mice receiving daily treatment, i.p., with quinpirole alone (A), with SCH23390 alone (B), with brain-impermeable dopamine (C), or with dopamine combined with SCH23390 (D) for 8 consecutive days. (E) Confocal images taken from the midbrain area of WT and Trappc9-KO mouse brain sections stained with antibodies for neuronal marker NeuN (red), dopaminergic neuronal marker TH (green), and DNA dyes (blue). Boxed regions within the VTA and SN, respectively, were enlarged as insets of original magnification, ×3.5. VTA, ventral tegmental area; SN, substantia nigra. Stereology counting of somata containing both NeuN and TH (F) and densitometric quantification of TH signals (G) within the indicated area closed with a contour in confocal images (E). Confocal images used for quantitative analyses were obtained from 3 consecutive brain sections from each brain (N = 3 mice per genotype). (H) Western blot analysis of whole brain lysates followed by densitometry of TH immunoreactive signals (I). (J) Comparison of dopamine levels in whole brain lysates of WT and Trappc9-KO mice. Pharmacological studies (AD) were performed with 7 mice per genotype. Each symbol in bar graphs (F, G, I, and J) represents 1 animal. Data are mean ± SD. Two-tailed Student’s t test: ***P < 0.005; #P < 0.0001.