Class 3 PI3K Coactivates the Circadian Clock to Promote Rhythmic De Novo Purine Synthesis

Overview

Journal Nat Cell Biol

Specialty Cell Biology

Date 2023 Jul 6

PMID 37414850

Authors

Chantal Alkhoury

Nathaniel F Henneman

Volodymyr Petrenko

Yui Shibayama

Arianna Segaloni

Alexis Gadault

Ivan Nemazanyy

Edouard Le Guillou

Amare Desalegn Wolide

Konstantina Antoniadou

Xin Tong

Teruya Tamaru

Takeaki Ozawa

Muriel Girard

Karim Hnia

Dominik Lutter

Charna Dibner

Ganna Panasyuk

Affiliations

Soon will be listed here.

Abstract

Metabolic demands fluctuate rhythmically and rely on coordination between the circadian clock and nutrient-sensing signalling pathways, yet mechanisms of their interaction remain not fully understood. Surprisingly, we find that class 3 phosphatidylinositol-3-kinase (PI3K), known best for its essential role as a lipid kinase in endocytosis and lysosomal degradation by autophagy, has an overlooked nuclear function in gene transcription as a coactivator of the heterodimeric transcription factor and circadian driver Bmal1-Clock. Canonical pro-catabolic functions of class 3 PI3K in trafficking rely on the indispensable complex between the lipid kinase Vps34 and regulatory subunit Vps15. We demonstrate that although both subunits of class 3 PI3K interact with RNA polymerase II and co-localize with active transcription sites, exclusive loss of Vps15 in cells blunts the transcriptional activity of Bmal1-Clock. Thus, we establish non-redundancy between nuclear Vps34 and Vps15, reflected by the persistent nuclear pool of Vps15 in Vps34-depleted cells and the ability of Vps15 to coactivate Bmal1-Clock independently of its complex with Vps34. In physiology we find that Vps15 is required for metabolic rhythmicity in liver and, unexpectedly, it promotes pro-anabolic de novo purine nucleotide synthesis. We show that Vps15 activates the transcription of Ppat, a key enzyme for the production of inosine monophosphate, a central metabolic intermediate for purine synthesis. Finally, we demonstrate that in fasting, which represses clock transcriptional activity, Vps15 levels are decreased on the promoters of Bmal1 targets, Nr1d1 and Ppat. Our findings open avenues for establishing the complexity for nuclear class 3 PI3K signalling for temporal regulation of energy homeostasis.

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