Creatine transporter deficiency impairs stress adaptation and brain energetics homeostasis
Hong-Ru Chen, Xiaohui Zhang-Brotzge, Yury M. Morozov, Yuancheng Li, Siming Wang, Helen Heju Zhang, Irena S. Kuan, Elizabeth M. Fugate, Hui Mao, Yu-Yo Sun, Pasko Rakic, Diana M. Lindquist, Ton DeGrauw, Chia-Yi Kuan
Hong-Ru Chen, Xiaohui Zhang-Brotzge, Yury M. Morozov, Yuancheng Li, Siming Wang, Helen Heju Zhang, Irena S. Kuan, Elizabeth M. Fugate, Hui Mao, Yu-Yo Sun, Pasko Rakic, Diana M. Lindquist, Ton DeGrauw, Chia-Yi Kuan
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Research Article Metabolism Neuroscience

Creatine transporter deficiency impairs stress adaptation and brain energetics homeostasis

Abstract

The creatine transporter (CrT) maintains brain creatine (Cr) levels, but the effects of its deficiency on energetics adaptation under stress remain unclear. There are also no effective treatments for CrT deficiency, the second most common cause of X-linked intellectual disabilities. Herein, we examined the consequences of CrT deficiency in brain energetics and stress-adaptation responses plus the effects of intranasal Cr supplementation. We found that CrT-deficient (CrT–/y) mice harbored dendritic spine and synaptic dysgenesis. Nurtured newborn CrT–/y mice maintained baseline brain ATP levels, with a trend toward signaling imbalance between the p-AMPK/autophagy and mTOR pathways. Starvation elevated the signaling imbalance and reduced brain ATP levels in P3 CrT–/y mice. Similarly, CrT–/y neurons and P10 CrT–/y mice showed an imbalance between autophagy and mTOR signaling pathways and greater susceptibility to cerebral hypoxia-ischemia and ischemic insults. Notably, intranasal administration of Cr after cerebral ischemia increased the brain Cr/N-acetylaspartate ratio, partially averted the signaling imbalance, and reduced infarct size more potently than intraperitoneal Cr injection. These findings suggest important functions for CrT and Cr in preserving the homeostasis of brain energetics in stress conditions. Moreover, intranasal Cr supplementation may be an effective treatment for congenital CrT deficiency and acute brain injury.

Authors

Hong-Ru Chen, Xiaohui Zhang-Brotzge, Yury M. Morozov, Yuancheng Li, Siming Wang, Helen Heju Zhang, Irena S. Kuan, Elizabeth M. Fugate, Hui Mao, Yu-Yo Sun, Pasko Rakic, Diana M. Lindquist, Ton DeGrauw, Chia-Yi Kuan

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Figure 1

Generation of CrT-null mice.

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Generation of CrT-null mice. (A) The scheme to generate CrT-null (CrT–/y...
(A) The scheme to generate CrT-null (CrT–/y) mice using the knockout-first strategy via an ES cell line from the NIH KOMP Repository (CSD24513). The locations of PCR primers to detect the CrT-targeted genomic allele are indicated. (B) Schematic of primer design for RT-qPCR analysis of different regions of the CrT (Slc6a8) mRNA. (C) PCR analysis of the genomic DNA of CrT+/y and CrT–/y mice to verify the wild-type and knockout alleles. The RT-PCR product (243 bp) from primers F3 and R3 corresponds to the region overlapping exon 3 and exon 4 sequences of both CrT+/y and CrT–/y cDNA; the 344 bp and 220 bp RT-qPCR products from primers F4 and R4 and F2 and R2, respectively, correspond to the region overlapping exon 5 to exon 10, which was missing in the CrT–/y cDNA. (D) PCR analysis of different regions of the CrT mRNA of CrT+/y and CrT–/y mice. (E) RT-qPCR showed the absence of full-length CrT mRNAs in the brain, heart, liver, skeletal muscles, and kidney in CrT–/y mice (n = 4). (F and G) Proton–HR-MAS NMR showed severe reduction in Cr/PCr peaks in the brain (arrows and asterisks), but not the testis, of CrT–/y mice (n = 5 for each genotype). All data are shown as mean ± SEM. All P values were determined by Student’s t test.