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Glycine decarboxylase deficiency–induced motor dysfunction in zebrafish is rescued by counterbalancing glycine synaptic level
Raphaëlle Riché, Meijiang Liao, Izabella A. Pena, Kit-Yi Leung, Nathalie Lepage, Nicolas D.E. Greene, Kyriakie Sarafoglou, Lisa A. Schimmenti, Pierre Drapeau, Éric Samarut
Raphaëlle Riché, Meijiang Liao, Izabella A. Pena, Kit-Yi Leung, Nathalie Lepage, Nicolas D.E. Greene, Kyriakie Sarafoglou, Lisa A. Schimmenti, Pierre Drapeau, Éric Samarut
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Research Article Genetics Neuroscience

Glycine decarboxylase deficiency–induced motor dysfunction in zebrafish is rescued by counterbalancing glycine synaptic level

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Abstract

Glycine encephalopathy (GE), or nonketotic hyperglycinemia (NKH), is a rare recessive genetic disease caused by defective glycine cleavage and characterized by increased accumulation of glycine in all tissues. Here, based on new case reports of GLDC loss-of-function mutations in GE patients, we aimed to generate a zebrafish model of severe GE in order to unravel the molecular mechanism of the disease. Using CRISPR/Cas9, we knocked out the gldc gene and showed that gldc–/– fish recapitulate GE on a molecular level and present a motor phenotype reminiscent of severe GE symptoms. The molecular characterization of gldc–/– mutants showed a broad metabolic disturbance affecting amino acids and neurotransmitters other than glycine, with lactic acidosis at stages preceding death. Although a transient imbalance was found in cell proliferation in the brain of gldc–/– zebrafish, the main brain networks were not affected, thus suggesting that GE pathogenicity is mainly due to metabolic defects. We confirmed that the gldc–/– hypotonic phenotype is due to NMDA and glycine receptor overactivation, and demonstrated that gldc–/– larvae depict exacerbated hyperglycinemia at these synapses. Remarkably, we were able to rescue the motor dysfunction of gldc–/– larvae by counterbalancing pharmacologically or genetically the level of glycine at the synapse.

Authors

Raphaëlle Riché, Meijiang Liao, Izabella A. Pena, Kit-Yi Leung, Nathalie Lepage, Nicolas D.E. Greene, Kyriakie Sarafoglou, Lisa A. Schimmenti, Pierre Drapeau, Éric Samarut

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Figure 7

Genetically and pharmacologically counteracting the exacerbated hyperglycinemia at the synapse rescues the motor phenotype of gldc–/– larvae.

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Genetically and pharmacologically counteracting the exacerbated hypergly...
(A) Overnight treatment with 5 μM strychnine significantly rescues the hypotonic swimming of gldc–/– larvae (n = 6) at 7 days compared with vehicle-treated gldc–/– (n = 11). (B) Overnight treatment with 50 μM dextromethorphan decreases the hypotonic coiling of gldc–/– (n = 23) compared with vehicle-treated gldc–/– embryos (n = 27) at 21 hpf. (C) Daily 25-μM dextromethorphan treatment over 7 days significantly rescues the hypotonic swimming of gldc–/– (n = 4) at 7 days, compared with vehicle-treated gldc–/– larvae (n = 6). (D) First-cell stage glycine transporter 1 (GlyT1) mRNA injection rescues the coiling defect of gldc–/– embryos at 21 hours after fertilization compared with GFP-injected gldc–/– (n > 15, N = 4). Statistical analysis were performed with ANOVA, and significant results are shown with asterisks (*P < 0.05; **P < 0.005; ***P < 0.0001). (E) Model representation of NMDA and glycine synapses of gldc–/– compared with gldc+/+ fish. gldc–/– fish have exacerbated hyperglycinemia at these synapses due to a decrease in GlyT1 and an increase in the levels of sarcosine. Boxes and whiskers represent minimum and maximum values, and a line shows the median value. Each dot corresponds to an individual experiment (N) of at least 5 fish (n > 5).

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