Epigenetic Regulation of Global Proteostasis Dynamics by RBBP5 Ensures Mammalian Organismal Health

Overview

Journal bioRxiv

Date 2024 Sep 24

PMID 39314427

Authors

Syeda Kubra

Michelle Sun

William Dion

Ahmet Catak

Hannah Luong

Haokun Wang

Yinghong Pan

Jia-Jun Liu

Aishwarya Ponna

Ian Sipula

Michael J Jurczak

Silvia Liu

Bokai Zhu

Affiliations

Soon will be listed here.

Abstract

Proteostasis is vital for cellular health, with disruptions leading to pathologies including aging, neurodegeneration and metabolic disorders. Traditionally, proteotoxic stress responses were studied as acute reactions to various noxious factors; however, recent evidence reveals that many proteostasis stress-response genes exhibit ~12-hour ultradian rhythms under physiological conditions in mammals. These rhythms, driven by an XBP1s-dependent 12h oscillator, are crucial for managing proteostasis. By exploring the chromatin landscape of the murine 12h hepatic oscillator, we identified RBBP5, a key subunit of the COMPASS complex writing H3K4me3, as an essential epigenetic regulator of proteostasis. RBBP5 is indispensable for regulating both the hepatic 12h oscillator and transcriptional response to acute proteotoxic stress, acting as a co-activator for proteostasis transcription factor XBP1s. RBBP5 ablation leads to increased sensitivity to proteotoxic stress, chronic inflammation, and hepatic steatosis in mice, along with impaired autophagy and reduced cell survival . In humans, lower expression is associated with reduced adaptive stress-response gene expression and hepatic steatosis. Our findings establish RBBP5 as a central regulator of proteostasis, essential for maintaining mammalian organismal health.

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