Your search keyword '"Zunino, Rodolfo"' showing total 5 results

1. MAPL SUMOylation of Drp1 Stabilizes an ER/Mitochondrial Platform Required for Cell Death.

Author

Prudent, Julien, Zunino, Rodolfo, Sugiura, Ayumu, Mattie, Sevan, Shore, Gordon C., and McBride, Heidi M.

Subjects

*SMALL ubiquitin-related modifier proteins, *APOPTOSIS, *BAX protein, *LIPOSOMES, *ENDOPLASMIC reticulum, *MITOCHONDRIA

Abstract

Summary There has been evidence that mitochondrial fragmentation is required for apoptosis, but the molecular links between the machinery regulating dynamics and cell death have been controversial. Indeed, activated BAX and BAK can form functional channels in liposomes, bringing into question the contribution of mitochondrial dynamics in apoptosis. We now demonstrate that the activation of apoptosis triggers MAPL/MUL1-dependent SUMOylation of the fission GTPase Drp1, a process requisite for cytochrome c release. SUMOylated Drp1 functionally stabilizes ER/mitochondrial contact sites that act as hotspots for mitochondrial constriction, calcium flux, cristae remodeling, and cytochrome c release. The loss of MAPL does not alter the activation and assembly of BAX/BAK oligomers, indicating that MAPL is activated downstream of BAX/BAK. This work demonstrates how interorganellar contacts are dynamically regulated through active SUMOylation during apoptosis, creating a stabilized platform that signals cytochrome c release. [ABSTRACT FROM AUTHOR]

Published

2015

2. Sumo1 Conjugates Mitochondrial Substrates and Participates in Mitochondrial Fission

Author

Harder, Zdena, Zunino, Rodolfo, and McBride, Heidi

Subjects

*MITOCHONDRIA, *MITOCHONDRIAL dynamics, *BIOLOGICAL membranes, *VIDEO microscopy

Abstract

Mitochondrial fission requires the evolutionarily conserved dynamin related protein (DRP1), which is recruited from the cytosol to the mitochondrial outer membrane to coordinate membrane scission . Currently, the mechanism of recruitment and assembly of DRP1 on the mitochondria is unclear. Here, we identify Ubc9 and Sumo1 as specific DRP1-interacting proteins and demonstrate that DRP1 is a Sumo1 substrate. In addition, a surprising number of Sumo1 conjugates were observed in the mitochondrial fractions, suggesting that sumoylation is a common mitochondrial modification. Video microscopy demonstrates that YFP:Sumo1 is often found at the site of mitochondrial fission and remains tightly associated to the tips of fragmented mitochondria. Consistent with this, fluorescence microscopy revealed that a portion of total cytosolic YFP:Sumo1 colocalizes with endogenous mitochondrial DRP1. Finally, transient transfection of Sumo1 dramatically increases the level of mitochondrial fragmentation. Analysis of endogenous DRP1 levels indicates that overexpression of Sumo1 specifically protects DRP1 from degradation, resulting in a more stable, active pool of DRP1, which at least partially accounts for the excess fragmentation. Together, these data are the first to identify a function for Sumo1 on the mitochondria and suggest a novel role for the participation of Sumo1 in mitochondrial fission. [Copyright &y& Elsevier]

Published

2004

3. A Vesicular Transport Pathway Shuttles Cargo from Mitochondria to Lysosomes

Author

Soubannier, Vincent, McLelland, Gian-Luca, Zunino, Rodolfo, Braschi, Emelie, Rippstein, Peter, Fon, Edward A., and McBride, Heidi M.

Subjects

*MITOCHONDRIA, *LYSOSOMES, *ELECTRON transport, *REACTIVE oxygen species, *ENZYMATIC analysis, *ELECTRON microscopy

Abstract

Summary: Mitochondrial respiration relies on electron transport, an essential yet dangerous process in that it leads to the generation of reactive oxygen species (ROS). ROS can be neutralized within the mitochondria through enzymatic activity, yet the mechanism for steady-state removal of oxidized mitochondrial protein complexes and lipids is not well understood. We have previously characterized vesicular profiles budding from the mitochondria that carry selected cargo []. At least one population of these mitochondria-derived vesicles (MDVs) targets the peroxisomes; however, the fate of the majority of MDVs was unclear. Here, we demonstrate that MDVs carry selected cargo to the lysosomes. Using a combination of confocal and electron microscopy, we observe MDVs in steady state and demonstrate that they are stimulated as an early response to oxidative stress, the extent of which is determined by the respiratory status of the mitochondria. Delivery to the lysosomes does not require mitochondrial depolarization and is independent of ATG5 and LC3, suggesting that vesicle delivery complements mitophagy. Consistent with this, ultrastructural analysis of MDV formation revealed Tom20-positive structures within the vesicles of multivesicular bodies. These data characterize a novel vesicle transport route between the mitochondria and lysosomes, providing insights into the basic mechanisms of mitochondrial quality control. [ABSTRACT FROM AUTHOR]

Published

2012

4. Vps35 Mediates Vesicle Transport between the Mitochondria and Peroxisomes

Author

Braschi, Emélie, Goyon, Vanessa, Zunino, Rodolfo, Mohanty, Abhishek, Xu, Liqun, and McBride, Heidi M.

Subjects

*MITOCHONDRIA formation, *PEROXISOMES, *LIGASES, *SYNAPTIC vesicles, *PEROXIDES, *GOLGI apparatus

Abstract

Summary: Mitochondria-derived vesicles (MDVs) have been shown to transport cargo from the mitochondria to the peroxisomes []. Mitochondria and peroxisomes share common functions in the oxidation of fatty acids and the reduction of damaging peroxides []. Their biogenesis is also linked through both the activation of master transcription factors such as PGC-1α [] and the common use of fission machinery, including DRP1, Mff, and hFis1 []. We have previously shown that MDVs are formed independently of the known mitochondrial fission GTPase Drp1 and are enriched for a mitochondrial small ubiquitin-like modifier (SUMO) E3 ligase called MAPL (mitochondrial-anchored protein ligase) []. Here, we demonstrate that the retromer complex, a known component of vesicle transport from the endosome to the Golgi apparatus [], regulates the transport of MAPL from mitochondria to peroxisomes. An unbiased screen shows that Vps35 and Vps26 are found in complex with MAPL, and confocal imaging reveals Vps35 recruitment to mitochondrial vesicles. Silencing of Vps35 or Vps26A leads to a significant reduction in the delivery of MAPL to peroxisomes, placing the retromer within a novel intracellular trafficking route and providing insight into the formation of MAPL-positive MDVs. [Copyright &y& Elsevier]

Published

2010

5. Cargo-Selected Transport from the Mitochondria to Peroxisomes Is Mediated by Vesicular Carriers

Author

Neuspiel, Margaret, Schauss, Astrid C., Braschi, Emelie, Zunino, Rodolfo, Rippstein, Peter, Rachubinski, Richard A., Andrade-Navarro, Miguel A., and McBride, Heidi M.

Subjects

*PEROXISOMES, *MITOCHONDRIA, *PROTOPLASM, *OXIDATION

Abstract

Summary: Mitochondria and peroxisomes share a number of common biochemical processes, including the β oxidation of fatty acids and the scavenging of peroxides. Here, we identify a new outer-membrane mitochondria-anchored protein ligase (MAPL) containing a really interesting new gene (RING)-finger domain. Overexpression of MAPL leads to mitochondrial fragmentation, indicating a regulatory function controlling mitochondrial morphology. In addition, confocal- and electron-microscopy studies of MAPL-YFP led to the observation that MAPL is also incorporated within unique, DRP1-independent, 70–100 nm diameter mitochondria-derived vesicles (MDVs). Importantly, vesicles containing MAPL exclude another outer-membrane marker, TOM20, and vesicles containing TOM20 exclude MAPL, indicating that MDVs selectively incorporate their cargo. We further demonstrate that MAPL-containing vesicles fuse with a subset of peroxisomes, marking the first evidence for a direct relationship between these two functionally related organelles. In contrast, a distinct vesicle population labeled with TOM20 does not fuse with peroxisomes, indicating that the incorporation of specific cargo is a primary determinant of MDV fate. These data are the first to identify MAPL, describe and characterize MDVs, and define a new intracellular transport route between mitochondria and peroxisomes. [Copyright &y& Elsevier]

Published

2008