MTOR-related Neuropathology in Mutant Tsc2 Zebrafish: Phenotypic, Transcriptomic and Pharmacological Analysis

Overview

Journal Neurobiol Dis

Specialty Neurology

Date 2017 Sep 11

PMID 28888969

Citations 21

Authors

Chloe Scheldeman

James D Mills

Aleksandra Siekierska

Ines Serra

Danielle Copmans

Anand M Iyer

Benjamin J Whalley

Jan Maes

Anna C Jansen

Lieven Lagae

Eleonora Aronica

Peter A M de Witte

Affiliations

Soon will be listed here.

Abstract

Tuberous sclerosis complex (TSC) is a rare, genetic disease caused by loss-of-function mutations in either TSC1 or TSC2. Patients with TSC are neurologically characterized by the presence of abnormal brain structure, intractable epilepsy and TSC-associated neuropsychiatric disorders. Given the lack of effective long-term treatments for TSC, there is a need to gain greater insight into TSC-related pathophysiology and to identify and develop new treatments. In this work we show that homozygous tsc2 mutant zebrafish larvae, but not tsc2 and WT larvae, display enlarged brains, reduced locomotor behavior and epileptiform discharges at 7dpf. In addition, we pharmacologically validated the TSC model by demonstrating the dramatic rescue effect of pericardially injected rapamycin, a well-known mTOR inhibitor, on selected behavioral read-outs and at the molecular level. By means of trancriptome profiling we also acquired more insight into the neuropathology of TSC, and as a result were able to highlight possible new treatment targets. The gene expression profiles of WT and tsc2 larvae revealed 117 differentially expressed genes (DEGs), while between WT and tsc2 larvae and tsc2 and tsc2 larvae there were 1414 and 1079 DEGs, respectively. Pathway enrichment analysis from the WT and tsc2 DEGs, identified 14 enriched pathways from the up-regulated genes and 6 enriched pathways from the down-regulated genes. Moreover, genes related to inflammation and immune response were up-regulated in the heads of tsc2 larvae, in line with the findings in human brain tissue where inflammatory and immune responses appear to be major hallmarks of TSC. Taken together, our phenotypic, transcriptomic and pharmacological analysis identified the tsc2 zebrafish as a preclinical model that mirrors well aspects of the human condition and delineated relevant TSC-related biological pathways. The model may be of value for future TSC-related drug discovery and development programs.

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