Cilia Defects Upon Loss of WDR4 Are Linked to Proteasomal Hyperactivity and Ubiquitin Shortage

Overview

Journal Cell Death Dis

Specialties Cell Biology
General Medicine

Date 2024 Sep 9

PMID 39251572

Authors

Martin D Burkhalter

Tom Stiff

Lars D Maerz

Teresa Casar Tena

Heike Wiese

Julian Gerhards

Steffen A Sailer

Linh Anna Truc Vu

Max Duong Phu

Cornelia Donow

Marius Alupei

Sebastian Iben

Marco Groth

Sebastian Wiese

Joseph A Church

Penelope A Jeggo

Melanie Philipp

Affiliations

Soon will be listed here.

Abstract

The WD repeat-containing protein 4 (WDR4) has repeatedly been associated with primary microcephaly, a condition of impaired brain and skull growth. Often, faulty centrosomes cause microcephaly, yet aberrant cilia may also be involved. Here, we show using a combination of approaches in human fibroblasts, zebrafish embryos and patient-derived cells that WDR4 facilitates cilium formation. Molecularly, we associated WDR4 loss-of-function with increased protein synthesis and concomitant upregulation of proteasomal activity, while ubiquitin precursor pools are reduced. Inhibition of proteasomal activity as well as supplementation with free ubiquitin restored normal ciliogenesis. Proteasome inhibition ameliorated microcephaly phenotypes. Thus, we propose that WDR4 loss-of-function impairs head growth and neurogenesis via aberrant cilia formation, initially caused by disturbed protein and ubiquitin homeostasis.

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