Litcius/Paper detail

Wdfy3 regulates glycophagy, mitophagy, and synaptic plasticity

Eleonora Napoli, Alexios A. Panoutsopoulos, Patricia Kysar, Nathaniel Satriya, Kira Sterling, Bradley Shibata, Denise M. Imai, David N. Ruskin, Konstantinos Zarbalis, Cecilia Giulivi

2021Journal of Cerebral Blood Flow & Metabolism21 citationsDOIOpen Access PDF

Abstract

Autophagy is essential to cell function, as it enables the recycling of intracellular constituents during starvation and in addition functions as a quality control mechanism by eliminating spent organelles and proteins that could cause cellular damage if not properly removed. Recently, we reported on Wdfy3's role in mitophagy, a clinically relevant macroautophagic scaffold protein that is linked to intellectual disability, neurodevelopmental delay, and autism spectrum disorder. In this study, we confirm our previous report that Wdfy3 haploinsufficiency in mice results in decreased mitophagy with accumulation of mitochondria with altered morphology, but expanding on that observation, we also note decreased mitochondrial localization at synaptic terminals and decreased synaptic density, which may contribute to altered synaptic plasticity. These changes are accompanied by defective elimination of glycogen particles and a shift to increased glycogen synthesis over glycogenolysis and glycophagy. This imbalance leads to an age-dependent higher incidence of brain glycogen deposits with cerebellar hypoplasia. Our results support and further extend Wdfy3's role in modulating both brain bioenergetics and synaptic plasticity by including glycogen as a target of macroautophagic degradation.

Topics & Concepts

MitophagyGlycogenBiologySynaptic plasticityNeuroscienceCell biologyMitochondrionAutophagyEndocrinologyBiochemistryApoptosisReceptorGenetics and Neurodevelopmental DisordersGlycogen Storage Diseases and MyoclonusAutophagy in Disease and Therapy