Abstract
Mitochondria are multifunctional organelles that essentially contribute to cell signaling by sophisticated mechanisms of communications. Live cell imaging studies showed that mitochondria are dynamic and complex structures that form ramified networks by directed movements, fission, and fusion events. There is emerging evidence that the morphology of mitochondria determines cellular functions and vice versa. Several intracellular signaling pathways and messengers including Ca2+ dynamically influence the architecture of mitochondria. Because electron microscopy cannot be utilized for an assessment of dynamics of mitochondrial morphology in intact cells, most studies were performed using wide-field or laser confocal fluorescence microscopies that, due to limitations of their spatial resolution, do not allow investigating sub-mitochondrial structures. Accordingly, our understanding of the dynamics of substructures of mitochondria is quite limited. Here, we present a robust super-resolution method to quantify the dynamics of mitochondrial cristae, the main substructures of the inner mitochondrial membrane, exploiting structured illumination microscopy (SIM). We observed that knockdown of the dynamin-like 120-kDa protein, which is encoded by the OPA1 gene, specifically reduces the dynamics of the mitochondrial cristae membranes (CM), while the inner boundary membrane (IBM) remained flexible. We further used dual color SIM to quantify the dynamics of CM in the junction between mitochondria and the endoplasmic reticulum (ER; mitochondrial associated membranes, MAMs). Intracellular Ca2+ release spatially reduced CM-dynamics in MAMs. Moreover, CM-dynamics was independent from matrix Ca2+ signal. Our data suggest that local Ca2+ signals specifically control CM-dynamics and structure to facilitate a well-balanced functional (Ca2+) interplay between mitochondria and the ER.
Highlights
The network of mitochondria in living cells represents a highly dynamic structure undergoing continuous fissionThis article is part of the special issue on Mitochondrial Signalling in Pflügers Archiv – European Journal of Physiology Electronic supplementary material The online version of this article contains supplementary material, which is available to authorized users.Pflugers Arch - Eur J Physiol (2018) 470:1193–1203 addition, the ATP synthase complex plays an essential role in cristae modeling
IBMchanges were subtracted for inner mitochondrial membrane (IMM)-changes revealing the dynamics of the cristae membranes (CM)
The overall pixel intensities of CM-changes were normalized to the global threshold area presenting the percentage of moving area inside the mitochondria. c The percentage of mitochondrial area moving per frame separated in the CM and inner boundary membrane (IBM) was quantified for control siRNA and OPA1 siRNA (n = 6). d Schematic representation of the IMM and the OPA1-controlled cristae junctions (CJ)
Summary
Pflugers Arch - Eur J Physiol (2018) 470:1193–1203 addition, the ATP synthase complex plays an essential role in cristae modeling. Dimerization of the ATP synthase and induction of membrane curvature is mandatory for normal cristae morphology [32]. A depletion of OPA1 leads to fragmentation of mitochondria and evokes drastic disorganization of the cristae [1, 5, 22] and increased susceptibility to apoptosis [24]. Cristae shape, respiratory chain super-complexes, complex-I-dependent respiration, and respiratory growth are impaired after OPA1 depletion [6]. OPA1 might play a role in mitochondrial Ca2+ signaling as knock down of OPA1 enhances Ca2+ influx into mitochondria by increasing the access of Ca2+ to the transporters in the cristae membrane [12]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
