Parkin promotes the ubiquitination and degradation of the mitochondrial fusion factor mitofusin 1

Liliane Glauser, Darren Moore, Sarah Catherine Sonnay, Klodjan Stafa
2011
Journal paper

Abstract

Mutations in the parkin gene cause early-onset, autosomal recessive Parkinson's disease. Parkin functions as an E3 ubiquitin ligase to mediate the covalent attachment of ubiquitin monomers or linked chains to protein substrates. Substrate ubiquitination can target proteins for proteasomal degradation or can mediate a number of non-degradative functions. Parkin has been shown to preserve mitochondrial integrity in a number of experimental systems through the regulation of mitochondrial fission. Upon mitochondrial damage, parkin translocates to mitochondria to mediate their selective elimination by autophagic degradation. The mechanism underlying this process remains unclear. Here, we demonstrate that parkin interacts with and selectively mediates the atypical poly-ubiquitination of the mitochondrial fusion factor, mitofusin 1, leading to its enhanced turnover by proteasomal degradation. Our data supports a model whereby the translocation of parkin to damaged mitochondria induces the degradation of mitofusins leading to impaired mitochondrial fusion. This process may serve to selectively isolate damaged mitochondria for their removal by autophagy.

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Liliane Glauser, Darren Moore, Sarah Catherine Sonnay, Klodjan Stafa
2011
Journal paper

Abstract

Official source

https://infoscience.epfl.ch/record/171201?ln=en

About this result

Related concepts (13)

A mitochondrion (ˌmaɪtəˈkɒndriən; : mitochondria) is an organelle found in the cells of most eukaryotes, such as animals, plants and fungi. Mitochondria have a double membrane structure and use aer

Autophagy (or autophagocytosis; from the Ancient Greek αὐτόφαγος, , meaning "self-devouring" and κύτος, , meaning "hollow") is the natural, conserved degradation of the cell that removes unnecessary

Ubiquitin is a small (8.6 kDa) regulatory protein found in most tissues of eukaryotic organisms, i.e., it is found ubiquitously. It was discovered in 1975 by Gideon Goldstein

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Related publications (10)

Related publications

Parkin functionally interacts with PGC-1 proportional to to preserve mitochondria and protect dopaminergic neurons

Patrick Aebischer, Johan Auwerx, Nathalie Marie Géraldine Bernard, Graham Knott, Darren Moore, Norman Lionel Moullan, Bernard Schneider, Lu Zheng

To understand the cause of Parkinson's disease (PD), it is important to determine the functional interactions between factors linked to the disease. Parkin is associated with autosomal recessive early-onset PD, and controls the transcription of PGC-1a, a master regulator of mitochondrial biogenesis. These two factors functionally interact to regulate the turnover and quality of mitochondria, by increasing both mitophagic activity and mitochondria biogenesis. In cortical neurons, co- expressing PGC-1a and Parkin increases the number of mitochondria, enhances maximal respiration, and accelerates the recovery of the mitochondrial membrane potential following mitochondrial uncoupling. PGC-1a enhances Mfn2 transcription, but also leads to increased degradation of the Mfn2 protein, a key ubiquitylation target of Parkin on mitochondria. In vivo, Parkin has significant protective effects on the survival and function of nigral dopaminergic neurons in which the chronic expression of PGC1a is induced. Ultrastructural analysis shows that these two factors together control the density of mitochondria and their interaction with the endoplasmic reticulum. These results highlight the combined effects of Parkin and PGC- 1a in the maintenance of mitochondrial homeostasis in dopaminergic neurons. These two factors synergistically control the quality and function of mitochondria, which is important for the survival of neurons in Parkinson's disease.

Oxford Univ Press2017

Identification of genetic determinants and pharmacological modulators of mitochondrial function

Pénélope Andreux

Increased life expectancy goes hand in hand with a higher incidence of age-related diseases that affect the nervous and metabolic systems, such as type 2 diabetes, cancer, Parkinson’s and Alzheimer’s disease. These complex diseases are a product of the combined actions of large networks of genes, and environmental factors, such as diet, exercise, drug use, and levels of acute and chronic stress. One of the main challenges in biomedical research is determining how these factors interact to influence human healthspan, in order to develop effective strategies for the diagnosis, prevention, and treatment of these chronic multifactorial diseases. A strategy that has emerged in the last decade is the modulation of mitochondrial function. Accumulating evidence support the involvement of mitochondrial dysfunction in the pathogenesis of type 2 diabetes, Parkinson’s disease, cancer, and to a lesser extent, Alzheimer’s disease. Mitochondrial processes are regulated by a highly dynamic and complex network of enzymes and transcription factors. One of the best characterized branches of this network is the AMPK/SIRT1 pathway and its downstream effectors. Recently, additional pathways important for the regulation of mitochondrial function have been described such as mitochondrial fusion and fission, specific autophagy of mitochondria, termed mitophagy, and mitochondrial unfolded protein response (UPRmt). These recent discoveries have extended the scope of potential therapeutic targets. This thesis describes the development of two complementary approaches to identify novel genetic and pharmacological determinants of mitochondrial function. 1. The first approach aims to identify novel genetic determinants of the regulatory networks that control metabolism in general, and mitochondrial function in particular, by using the mouse BXD genetic reference population (GRP). Chapter II summarizes the analysis of 140 metabolic traits in 42 BXD strains, and demonstrates the suitability and usefulness of the BXD GRP for the identification of genetic regulators of metabolism. 2. The second approach is focused on the development of pharmacological tests for the identification and characterization of novel drugs that modulate mitochondrial phenotypes. Chapter III presents the establishment and validation of a platform of mitochondrial assays in two species, i.e. mammalian cells and the worm C.elegans. A successful example of its use is shown in chapter IV, where the role of copper in tumorigenesis is elucidated by applying these mitochondrial assays Altogether, these two synergistic approaches pave the way that will lead to the identification of novel key factors and treatments for mitochondrial diseases and pathologies associated with mitochondrial dysfunction.

EPFL2013

In recent years, the role of acetylation has gained ground as an essential modulator of intermediary metabolism in skeletal muscle. Imbalance in energy homeostasis or chronic cellular stress, due to diet, aging, or disease, translate into alterations in the acetylation levels of key proteins which govern bioenergetics, cellular substrate use, and/or changes in mitochondrial content and function. For example, cellular stress induced by exercise or caloric restriction can alter the coordinated activity of acetyltransferases and deacetylases to increase mitochondrial biogenesis and function in order to adapt to low energetic levels. The natural duality of these enzymes, as metabolic sensors and effector proteins, has helped biologists to understand how the body can integrate seemingly distinct signaling pathways to control mitochondrial biogenesis, insulin sensitivity, glucose transport, reactive oxygen species handling, angiogenesis, and muscle satellite cell proliferation/differentiation. Our review will summarize the recent developments related to acetylation-dependent responses following metabolic stress in skeletal muscle.

Society for Endocrinology2013

Identification of genetic determinants and pharmacological modulators of mitochondrial function

Pénélope Andreux

EPFL2013