S-Sulfocysteine Induces Seizure-Like Behaviors in Zebrafish.

Jennifer Plate,Reinhard W Köster,Tobias Kruse,Ahmed H Hassan,Franziska Lehne,Wiebke A Sassen

doi:10.3389/fphar.2019.00122

Jennifer Plate, Reinhard W Köster + Show 4 more

Open Access

https://doi.org/10.3389/fphar.2019.00122

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Abstract

Sulfite is a neurotoxin, which is detoxified by the molybdenum cofactor (Moco)-dependent enzyme sulfite oxidase (SOX). In humans, SOX deficiency causes the formation of the glutamate analog S-Sulfocysteine (SSC) resulting in a constant overstimulation of ionotropic glutamatergic receptors. Overstimulation leads to seizures, severe brain damage, and early childhood death. SOX deficiency may be caused either by a mutated sox gene or by mutations in one of the genes of the multi-step Moco biosynthesis pathway. While patients affected in the first step of Moco biosynthesis can be treated by a substitution therapy, no therapy is available for patients affected either in the second or third step of Moco biosynthesis or with isolated SOX deficiency. In the present study, we used a combination of behavior analysis and vital dye staining to show that SSC induces increased swimming, seizure-like movements, and increased cell death in the central nervous system of zebrafish larvae. Seizure-like movements were fully revertible upon removal of SSC or could be alleviated by a glutamatergic receptor antagonist. We conclude that in zebrafish SSC can chemically induce phenotypic characteristics comparable to the disease condition of human patients lacking SOX activity.

Highlights

Molybdenum (Mo) is an essential element for life (Mendel, 2013), which for biological activity requires being complexed within the molybdenum cofactor (Moco)
No therapy is available for patients suffering under either MoCD caused by mutations affecting the second or third step of the Moco biosynthesis pathway (MoCD Types B and C) or isolated sulfite oxidase (SOX) deficiency (Johnson and Duran, 2001)
SSC-treated larvae were found to display all qualitative and quantitative characteristics defined for seizure-like behavior (Baraban et al, 2005) as demonstrated by visual and statistical evaluations, leading us to the conclusion that SSC can be used to chemically induce a highly reproducible and robust phenotypic model for MoCD and isolated SOX deficiency in zebrafish

Summary

Introduction

Molybdenum (Mo) is an essential element for life (Mendel, 2013), which for biological activity requires being complexed within the molybdenum cofactor (Moco). SSC is highly abundant in MoCD and isolated SOX deficiency patients (Schwarz, 2016) It causes neuronal hyperexcitation resulting in severe seizures in newborns, S-Sulfocysteine Induces Seizure-Like Behaviors neuronal cell death, and lethal brain damage (Johnson and Duran, 2001; Schwahn et al, 2015). No therapy is available for patients suffering under either MoCD caused by mutations affecting the second or third step of the Moco biosynthesis pathway (MoCD Types B and C) or isolated SOX deficiency (Johnson and Duran, 2001). We present a SSC-induced phenotypic model for MoCD and isolated SOX deficiency in zebrafish

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