4-Phenylbutyrate ameliorates apoptotic neural cell death in Down syndrome by reducing protein aggregates

Katsuya Hirata,Hidetoshi Taniguchi,Kazuko Wada,Kimihiko Banno,Mahito Nakanishi,Hitomi Arahori,Manami Ohtaka,Ken Nishimura,Yasuji Kitabatake,Keiichi Ozono,Nobutoshi Nawa,Hidetaka Yoshimatsu,Haruna Kusakabe,Toshihiko Nambara,Keiji Kawatani

doi:10.1038/s41598-020-70362-x

Abstract

Individuals with Down syndrome (DS) commonly show unique pathological phenotypes throughout their life span. Besides the specific effects of dosage-sensitive genes on chromosome 21, recent studies have demonstrated that the gain of a chromosome exerts an adverse impact on cell physiology, regardless of the karyotype. Although dysregulated transcription and perturbed protein homeostasis are observed in common in human fibroblasts with trisomy 21, 18, and 13, whether and how this aneuploidy-associated stress acts on other cell lineages and affects the pathophysiology are unknown. Here, we investigated cellular stress responses in human trisomy 21 and 13 neurons differentiated from patient-derived induced pluripotent stem cells. Neurons of both trisomies showed increased vulnerability to apoptotic cell death, accompanied by dysregulated protein homeostasis and upregulation of the endoplasmic reticulum stress pathway. In addition, misfolded protein aggregates, comprising various types of neurodegenerative disease-related proteins, were abnormally accumulated in trisomic neurons. Intriguingly, treatment with sodium 4-phenylbutyrate, a chemical chaperone, successfully decreased the formation of protein aggregates and prevented the progression of cell apoptosis in trisomic neurons. These results suggest that aneuploidy-associated stress might be a therapeutic target for the neurodegenerative phenotypes in DS.

Highlights

Individuals with Down syndrome (DS) commonly show unique pathological phenotypes throughout their life span
We found that treatment with sodium 4-phenylbutyrate (4-PBA), a potent chemical chaperone compound, successfully reduced the protein aggregation in trisomic fibroblasts and prevented the progression of premature senescence in secondary fibroblasts derived from trisomy 21 induced pluripotent stem cells (iPSCs)
All iPSC clones used in the present study showed the typical morphology and expression of pluripotent markers, including OCT3/4 and SSEA4 (Fig. S1b)

Summary

Introduction

Individuals with Down syndrome (DS) commonly show unique pathological phenotypes throughout their life span. Studies using in vitro and in vivo experiments with postmortem brains, neural stem/ progenitor cells (NPCs), or induced pluripotent stem cells (iPSCs) derived from DS patients and DS mouse models have shown various levels of neuropathology, including reduced neurogenesis, impaired neuronal maturation, and accelerated neural cell death. These features arise from the extra copy of human chromosome 21 (Hsa21), and specific DS phenotypes are generally thought to be derived from the increased expression of a specific subset of dosage-sensitive genes on H sa[213]. This acute type of cognitive regression in DS cannot be explained by the simple gene-dosage effects on APP processing, and detailed mechanisms for these modifications in dementia have not been elucidated yet

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Conclusion