Abstract
As fundamental processes in mitochondrial dynamics, mitochondrial fusion, fission and transport are regulated by several core components, including Miro. As an atypical Rho-like small GTPase with high molecular mass, the exchange of GDP/GTP in Miro may require assistance from a guanine nucleotide exchange factor (GEF). However, the GEF for Miro has not been identified. While studying mitochondrial morphology in Drosophila, we incidentally observed that the loss of vimar, a gene encoding an atypical GEF, enhanced mitochondrial fission under normal physiological conditions. Because Vimar could co-immunoprecipitate with Miro in vitro, we speculated that Vimar might be the GEF of Miro. In support of this hypothesis, a loss-of-function (LOF) vimar mutant rescued mitochondrial enlargement induced by a gain-of-function (GOF) Miro transgene; whereas a GOF vimar transgene enhanced Miro function. In addition, vimar lost its effect under the expression of a constitutively GTP-bound or GDP-bound Miro mutant background. These results indicate a genetic dependence of vimar on Miro. Moreover, we found that mitochondrial fission played a functional role in high-calcium induced necrosis, and a LOF vimar mutant rescued the mitochondrial fission defect and cell death. This result can also be explained by vimar's function through Miro, because Miro’s effect on mitochondrial morphology is altered upon binding with calcium. In addition, a PINK1 mutant, which induced mitochondrial enlargement and had been considered as a Drosophila model of Parkinson’s disease (PD), caused fly muscle defects, and the loss of vimar could rescue these defects. Furthermore, we found that the mammalian homolog of Vimar, RAP1GDS1, played a similar role in regulating mitochondrial morphology, suggesting a functional conservation of this GEF member. The Miro/Vimar complex may be a promising drug target for diseases in which mitochondrial fission and fusion are dysfunctional.
Highlights
Mitochondrial fission, fusion and transport play important roles for the function of this organelle [1, 2]
Mitochondrial dynamics including fusion, fission and transport are essential for energy supply in eukaryotic cells; and defects in mitochondrial dynamics often result in premature aging and diseases such as Parkinson's disease (PD)
Among these GTPases, mitofusin1/mitofusin2 (MFN1/MFN2) and optic atrophy protein1 (OPA1) are the core components that are responsible for mitochondrial fusion [4,5,6,7], whereas dynamin-related protein 1 (Drp1) is the core component that is responsible for mitochondrial fission [8, 9]
Summary
Mitochondrial dynamics including fusion, fission and transport are essential for energy supply in eukaryotic cells; and defects in mitochondrial dynamics often result in premature aging and diseases such as Parkinson's disease (PD). Machinery, the Miro/Milton complex loads mitochondria onto microtubule through kinesin motor proteins; and regulates mitochondrial fusion and fission through unknown mechanisms. We identified Vimar as a new regulator of mitochondrial dynamics in Drosophila. We found that loss of vimar promoted mitochondrial shortening; and this function was mediated through Miro. In the pathophysiological conditions, including a Pink mutant to model PD and a calcium-overload induced stress to model neuronal necrosis in Drosophila, loss of vimar suppressed both aberrant mitochondrial fusion and fragmentation in PD and necrosis, respectively. Vimar/ RAP1GDS1 may be a great drug target to deal with diseases caused by defective mitochondrial dynamics
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