Summary Mitochondrial Ca2+ uptake via the uniporter is central to cell metabolism, signaling and survival. Recent studies identified MCU as the uniporter’s likely pore and MICU1, an EF-hand protein, as its critical regulator. How this complex decodes dynamic cytoplasmic [Ca2+] ([Ca2+]c) signals, to tune out small [Ca2+]c increases yet permit pulse transmission, remains unknown. We report that loss of MICU1 in mouse liver and cultured cells causes mitochondrial Ca2+ accumulation during small [Ca2+]c elevations, yet an attenuated response to agonist-induced [Ca2+]c pulses. The latter reflects loss of positive cooperativity, likely via the EF-hands. MICU1 faces the intermembrane space and responds to [Ca2+]c changes. Prolonged MICU1 loss leads to an adaptive increase in matrix Ca2+ binding, yet cells show impaired oxidative metabolism and sensitization to Ca2+ overload. Collectively, the data indicate that MICU1 senses the [Ca2+]c to establish the uniporter’s threshold and gain, thereby allowing mitochondria to properly decode different inputs.
The ER-mitochondrial junction provides a local calcium signaling domain that is critical for both matching energy production with demand and the control of apoptosis. Here, we visualize ER-mitochondrial contact sites and monitor the localized [Ca2+] changes ([Ca2+]ER-mt) using drug-inducible fluorescent interorganelle linkers. We show that all mitochondria have contacts with the ER but plasma membrane-mitochondrial contacts are less frequent because of interleaving ER stacks in both RBL-2H3 and H9c2 cells. Single mitochondria display discrete patches of ER contacts and show heterogeneity in the ER-mitochondrial Ca2+ transfer. Pericam-tagged linkers revealed IP3-induced [Ca2+]ER-mt signals that exceeded 9μM and endured buffering bulk cytoplasmic [Ca2+] increases. Altering linker length to modify the space available for the Ca2+ transfer machinery had a biphasic effect on [Ca2+]ER-mt signals. These studies provide direct evidence for the existence of high Ca2+ microdomains between the ER and mitochondria, and suggest an optimal gap width for efficient Ca2+ transfer.
Ca2+ flux across the mitochondrial inner membrane regulates bioenergetics, cytoplasmic Ca2+ signals and activation of cell death pathways1–11. Mitochondrial Ca2+ uptake occurs at regions of close apposition with intracellular Ca2+ release sites 12–14, driven by the inner membrane voltage generated by oxidative phosphorylation and mediated by a Ca2+ selective ion channel (MiCa15) called the uniporter16–18 whose complete molecular identity remains unknown. Mitochondrial calcium uniporter (MCU) was recently identified as the likely ion-conducting pore19, 20. In addition, MICU1 was identified as a mitochondrial regulator of uniporter-mediated Ca2+ uptake in HeLa cells 21. Here we identified CCDC90A, hereafter referred to as MCUR1 (Mitochondrial Calcium Uniporter Regulator 1), an integral membrane protein required for MCU-dependent mitochondrial Ca2+ uptake. MCUR1 binds to MCU and regulates ruthenium red-sensitive MCU-dependent Ca2+ uptake. MCUR1 knockdown does not alter MCU localization, but abrogates Ca2+ uptake by energized mitochondria in intact and permeabilized cells. Ablation of MCUR1 disrupts oxidative phosphorylation, lowers cellular ATP, and activates AMP kinase-dependent pro-survival autophagy. Thus, MCUR1 is a critical component of a mitochondrial uniporter channel complex required for mitochondrial Ca2+ uptake and maintenance of normal cellular bioenergetics.
Contact sites of endoplasmic reticulum (ER) and mitochondria locally convey calcium signals between the IP 3 receptors (IP3R) and the mitochondrial calcium uniporter, and are central to cell survival. It remains unclear whether IP3Rs also have a structural role in contact formation and whether the different IP3R isoforms have redundant functions. Using an IP3R-deficient cell model rescued with each of the three IP3R isoforms and an array of super-resolution and ultrastructural approaches we demonstrate that IP3Rs are required for maintaining ER-mitochondrial contacts. This role is independent of calcium fluxes. We also show that, while each isoform can support contacts, type 2 IP3R is the most effective in delivering calcium to the mitochondria. Thus, these studies reveal a non-canonical, structural role for the IP3Rs and direct attention towards the type 2 IP3R that was previously neglected in the context of ER-mitochondrial calcium signaling.
SUMMARY Mitochondrial Ca2+ uptake through the Ca2+ uniporter supports cell functions, including oxidative metabolism, while meeting tissue-specific calcium signaling patterns and energy needs. The molecular mechanisms underlying tissue-specific control of the uniporter are unknown. Here, we investigated a possible role for tissue-specific stoichiometry between the Ca2+-sensing regulators (MICUs) and pore unit (MCU) of the uniporter. Low MICU1:MCU protein ratio lowered the [Ca2+] threshold for Ca2+ uptake and activation of oxidative metabolism but decreased the cooperativity of uniporter activation in heart and skeletal muscle compared to liver. In MICU1-overexpressing cells, MICU1 was pulled down by MCU proportionally to MICU1 overexpression, suggesting that MICU1:MCU protein ratio directly reflected their association. Overexpressing MICU1 in the heart increased MICU1:MCU ratio, leading to liver-like mitochondrial Ca2+ uptake phenotype and cardiac contractile dysfunction. Thus, the proportion of MICU1-free and MICU1-associated MCU controls these tissue-specific uniporter phenotypes and downstream Ca2+ tuning of oxidative metabolism.
Background: Reactive oxygen species (ROS) affect cytoplasmic calcium signaling. Results: Superoxide anion causes oxidation of the IP 3 receptor and sensitization of calcium release to promote cytoplasmic calcium oscillations and mitochondrial calcium uptake. Conclusion: Physiologically relevant ROS controls cytoplasmic and mitochondrial calcium transport through IP 3 receptors. Significance: Mechanisms of calcium and ROS interactions are relevant for both physiological and pathophysiological signaling.
In dystrophic muscle, an increase in reactive oxygen species (ROS) production and sarcolemmal calcium (Ca 2þ) influx contributes to stretch-induced muscle damage however mechanistic insights into the activation of these pathways is lacking. In mdx myofibers (murine Duchenne muscular dystrophy), we have demonstrated that with mechanical stretch, the microtubule (MT) cytoskeleton is a critical mechano-transduction element for the activation of NADPH oxi-dase2 (Nox2) derived ROS production; a pathway we term X-ROS signaling [1]. Downstream, we showed that X-ROS sensitized stretch activated channels (SACs) to increase sarcolemmal Ca 2þ influx during stretch. The significance of the MT cytoskeleton activation of X-ROS in mdx was revealed when the acute targeting of MT density proffered protection from contraction induced damage. In mammalian cells, the MT network is a dynamic structure in which MT density is determined by the stability of MT filaments. Our initial studies used acute pharmacological stabilization (taxol) or destabilization (colchicine) to establish MT network density as critical for the mechano-activation of X-ROS. We now interrogate critical upstream pathways and use new pharmacological and molecular approaches to explore the role of endogenous modulators of MT stability and how they may contribute to the enhanced X-ROS in dystrophic skeletal muscle.
Growing evidence supports that mitochondrial calcium uptake is important for cell metabolism, signaling and survival. However, both the molecular nature of the mitochondrial Ca2+ transport sites and the calcium signals they respond to remained elusive. Recent RNA interference studies have identified new candidate proteins for Ca2+ uptake across the inner mitochondrial membrane, including LETM1, MCU, MICU1 and NCLX. The sensitivity of these factors to several drugs has been tested and in parallel, some new inhibitors of mitochondrial Ca2+ uptake have been described. This paper provides an update on the pharmacological aspects of the molecular mechanisms of the inner mitochondrial membrane Ca2+ transport.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.