Pathological consequences of MICU1 mutations on mitochondrial calcium signalling and bioenergetics

Bhosale, Gauri; Sharpe, Jenny A.; Koh, Amanda; Kouli, Antonina; Szabadkai, György; Duchen, Michael R.

doi:10.1016/j.bbamcr.2017.01.015

Cited by 50 publications

(62 citation statements)

References 62 publications

(90 reference statements)

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“…Thus, in the absence of MICU1, constitutive influx and efflux constitutes an ongoing Ca 2+ cycling across the IMM that establishes a new, higher steady-state [Ca 2+ ] m . These observations corroborate those in fibroblasts from patients with genetic defects in MICU1 that result in absence of MICU1 expression (Bhosale et al, 2017). Here, we have for the first time quantified the new steady-state [Ca 2+ ] m in cells lacking MICU1.…”

Section: Discussionsupporting

confidence: 87%

“…Here, we have for the first time quantified the new steady-state [Ca 2+ ] m in cells lacking MICU1. Perhaps surprisingly, resting [Ca 2+ ] m was ~300–400 nM, which while elevated compared with ~100 nM in WT cells, is not excessively high, suggesting that mitochondria in MICU1_KO cells may not be as Ca 2+ over-loaded as has been inferred (Mallilankaraman et al, 2012; Logan et al, 2013; Antony et al, 2016; Liu et al, 2016; Bhosale et al, 2017). Several mechanisms could account for why [Ca 2+ ] m is not elevated to much higher levels.…”

Section: Discussionmentioning

confidence: 77%

“…Nevertheless, pathogenesis in MICU1_KO animals is consistent with that expected from mitochondrial Ca 2+ overload (Liu et al, 2016). The relatively modest matrix free-Ca 2+ elevation under resting conditions may not be the (sole) cause of disease pathogenesis in animal models (Antony et al, 2016; Liu et al, 2016) and patients (Logan et al, 2013; Lewis-Smith et al, 2016; Bhosale et al, 2017). Rather, pathogenesis might be caused by sensitized gain-of-function responses to transient [Ca 2+ ] c signals up to the normal threshold of ~1.3 μM.…”

Section: Discussionmentioning

confidence: 99%

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MICU2 Restricts Spatial Crosstalk between InsP 3 R and MCU Channels by Regulating Threshold and Gain of MICU1-Mediated Inhibition and Activation of MCU

et al. 2017

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SUMMARY Ca2+ entry into mitochondria is mediated by the Ca2+ uniporter-channel complex containing MCU, the Ca2+-selective pore, and associated regulatory proteins. The roles of MICU proteins are controversial. MICU1 was proposed to be necessary for MCU activity whereas subsequent studies suggested it inhibits the channel in the low-cytoplasmic Ca2+ ([Ca2+]c) regime, a mechanism referred to as “gatekeeping”, that imposes a [Ca2+]c threshold for channel activation at ~1–3 μM. Here we measured MCU activity over a wide range of quantitatively-controlled and recorded [Ca2+]c. MICU1 alone can mediate gatekeeping as well as highly-cooperative activation of MCU activity, whereas the fundamental role of MICU2 is to regulate the threshold and gain of MICU1-mediated inhibition and activation of MCU. Our results provide a unifying model for the roles of the MICU1/2 hetero-dimer in MCU-channel regulation and suggest an evolutionary role for MICU2 in spatially restricting Ca2+ crosstalk between single InsP3R and MCU channels.

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Section: Discussionsupporting

confidence: 87%

Section: Discussionmentioning

confidence: 77%

Section: Discussionmentioning

confidence: 99%

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MICU2 Restricts Spatial Crosstalk between InsP 3 R and MCU Channels by Regulating Threshold and Gain of MICU1-Mediated Inhibition and Activation of MCU

et al. 2017

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“…The Glu 264 site is likely the same site in the MCU pore that was previously reported to bind cytosolic Ca 2+ with Kd ≤ 2 nM ( 6 ), and thus it should always be occupied by Ca 2+ under physiological conditions. The lowest cytosolic [Ca 2+ ] at which Ca 2+ permeation through the MCU pore can occur is ∼100 nM ( 22, 49, 50 ). At this concentration, Ca 2+ should start binding to the Asp 261 site, which reduces affinity for Ca 2+ binding at Glu 264 and makes permeation possible.…”

Section: Resultsmentioning

confidence: 99%

Structure of intact human MCU supercomplex with the auxiliary MICU subunits

Zhuo

Heng

Guo

et al. 2020

Preprint

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29The mitochondrial Ca 2+ uniporter (MCU) supercomplex is essential for mitochondrial Ca 2+ uptake. 30Here, we present high-resolution cryo-EM structures of human MCU-EMRE supercomplex (MES, 31 3.41 Å) and MCU-EMRE-MICU1-MICU2 supercomplex (MEMMS, 3.64 Å). MES adopts a V-32 shaped dimer architecture comprising two hetero-octamers, and a pair of MICU1-MICU2 hetero-33 dimers form a bridge across the two halves of MES to constitute an O-shaped architecture of MEMMS. 34The MES and MEMMS pore profiles are almost identical, with Ca 2+ in the selectivity filters and no 35 obstructions, indicating both channels are conductive. Contrary to the current model in which MICUs 36 block the MCU pore, MICU1-MICU2 dimers are located on the periphery of the MCU pores and do 37 not occlude them. However, MICU1-MICU2 dimers may modulate MCU gating by affecting the 38 matrix gate through the EMRE lever. 39 40 41 42 43 3 / 26 Introduction 44Mitochondrial Ca 2+ homeostasis regulates energy production, cell division, and cell death. The basic 45properties of mitochondrial Ca 2+ uptake have been firmly established (1-4). The Ca 2+ influx is 46 mediated by MCU, driven by membrane potential and using a uniporter mechanism (Ca 2+ transport is 47 not coupled to transport of any other ion) (5). Patch-clamp analysis of MCU currents demonstrated 48 that MCU is a channel with exceptionally high Ca 2+ selectivity (6). Further, Ca 2+ efflux is known to 49 involve two pathways: H + /Ca 2+ exchange (7) and Na + /Ca 2+ exchange (8). The homeostasis of 50 mitochondrial Ca 2+ must be exquisitely regulated to prevent wastage of energy from bidirectional Ca 2+ 51 flux (9-11). 52In 2010, an RNA silencing study highlighted that MICU1 (mitochondrial Ca 2+ uptake 1) represents the 53 founding member of a set of proteins required for high-capacity mitochondrial Ca 2+ uptake (12). In 54 2011, two groups independently reported the membrane protein MCU and proposed it as the pore-55 forming element of the long-sought mitochondrial Ca 2+ uniporter (13, 14), which was confirmed later 56 using whole-mitoplast voltage-clamping (15). In 2012, a paralog of MICU1, MICU2 (mitochondrial 57 Ca 2+ uptake 2), was shown to cooperatively regulate Ca 2+ uptake with MICU1 (16). In 2013, a genetic 58 study led to the characterization of MCUb (mitochondrial Ca 2+ uniporter b), a vertebrate specific 59 protein sharing ~ 50% sequence identity and the same membrane topology with MCU (17). Also in 60 2013, a previously uncharacterized protein, EMRE (essential MCU regulator), which was shown to be 61 essential for Ca 2+ uptake in metazoa, was affinity-purified from human cells in complex with MCU 62 (18). 63Even in the absence of structural data on the MCU complex, mitochondrial Ca 2+ uptake and its 64 regulation in mammals has been assumed to rely on a complex comprising MCU, EMRE, MICU1, 65 and MICU2 (10,(19)(20)(21). Previous models generally believe that MICU1 and MICU2 form a cap to 66 occlude the MCU channel in low [Ca 2+ ] conditions, and when [Ca 2+ ] is elevated, through ...

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“…This prevents futile Ca 2+ cycle and the associated bioenergetics costs required to maintain acceptably low mitochondrial Ca 2+ concentration. Such futile Ca 2+ cycle and ATP expenditure were recently demonstrated in cells harbouring MICU1 mutation by G. Bhosale and colleagues from M. Duchen’s laboratory [10]. Threshold created by MICU1 and MICU2 is an important mechanism for reducing the signal-to-noise ratio for the communication between Ca 2+ signalling and mitochondria.…”

Section: Er-mitochondria Junctions As Signalling Nanodomainsmentioning

confidence: 92%

Mitochondrial junctions with cellular organelles: Ca2+ signalling perspective

Tepikin

2018

Pflugers Arch - Eur J Physiol

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Cellular organelles form multiple junctional complexes with one another and the emerging research area dealing with such structures and their functions is undergoing explosive growth. A new research journal named “Contact” has been recently established to facilitate the development of this research field. The current consensus is to define an organellar junction by the maximal distance between the participating organelles; and the gap of 30 nm or less is considered appropriate for classifying such structures as junctions or membrane contact sites. Ideally, the organellar junction should have a functional significance, i.e. facilitate transfer of calcium, sterols, phospholipids, iron and possibly other substances between the organelles (Carrasco and Meyer in Annu Rev Biochem 80:973–1000, 2011; Csordas et al. in Trends Cell Biol 28:523–540, 2018; Phillips and Voeltz in Nat Rev Mol Cell Biol 17:69–82, 2016; Prinz in J Cell Biol 205:759–769, 2014). It is also important to note that the junction is not just a result of a random organelle collision but have active and specific formation, stabilisation and disassembly mechanisms. The nature of these mechanisms and their role in physiology/pathophysiology are the main focus of an emerging research field. In this review, we will briefly describe junctional complexes formed by cellular organelles and then focus on the junctional complexes that are formed by mitochondria with other organelles and the role of these complexes in regulating Ca2+ signalling.

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Pathological consequences of MICU1 mutations on mitochondrial calcium signalling and bioenergetics

Cited by 50 publications

References 62 publications

MICU2 Restricts Spatial Crosstalk between InsP 3 R and MCU Channels by Regulating Threshold and Gain of MICU1-Mediated Inhibition and Activation of MCU

MICU2 Restricts Spatial Crosstalk between InsP 3 R and MCU Channels by Regulating Threshold and Gain of MICU1-Mediated Inhibition and Activation of MCU

Structure of intact human MCU supercomplex with the auxiliary MICU subunits

Mitochondrial junctions with cellular organelles: Ca2+ signalling perspective

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