The role of mitochondrial restructuring in neuronal calcium homeostasis and excitotoxicity

Houlihan, Patrick Ryan

01 May 2013

Mitochondrial Ca2+ buffering is an important physiological modulator of neuronal signaling and bioenergetics, but this propensity toward Ca2+ regulation proves pathological during excitotoxic insult. Specifically, excessive mitochondrial Ca2+ uptake is a key component of glutamate toxicity within the penumbra surrounding the ischemic core following stroke. This mitochondrial toxicity and Ca2+ dyshomeostasis may be visualized in real time as delayed calcium deregulation (DCD). DCD is a predictor of neuronal, excitoxic death, and is composed of three phases: 1) an initial response; 2) a latent period of elevated, but stable cytosolic Ca2+; and 3) failure of mitochondrial Ca2+ retention, termed deregulation. The duration of the latent period is an index of neuronal resistance. Mitochondria are dynamic organelles that rapidly and reversibly undergo fission and fusion (MFF). MFF is tightly regulated by the phosphoregulation of fission inducing Drp1 at serine 656. Drp1-S656 phosphorelation is mediated by PKA/AKAP1, and it is dephosphorylated by PP2A/Bβ2. Phosphorylation of Drp1-S656 inactivates this contractile GTPase resulting in inhibition of mitochondrial fission and a shift toward elongated mitochondria. This PKA/AKAP1 dependent Drp1-S656 phosphorylation has proven to be neuroprotective. Likewise, attenuation of PP2A/Bβ2 signaling enhances neuronal survival during ischemia and excitotoxic insult. Based on the mitochondrial buffering role in excitotoxicity and MFF modulation of neuronal survival, we began investigating the role of Ca2+ buffering as a function of MFF during glutamate toxicity. Noted above, resistance to excitoticity is visualized by the duration of the DCD latent period. Overexpression of AKAP1 in cultured hippocampal neurons greatly prolonged DCD latency in a PKA dependent manner, while Bβ2 ablation prolonged DCD latency by hours. Pharmacological modulation of PKA required PDE4 inhibition to reproduce the AKAP1 observations. Preliminary experiments studying the effect of Bβ2 overexpression on matrix Ca2+ load suggests possible mechanism of MFF regulated of matrix Ca2+ accumulation. Using mtPericam DRG neurons as a model system for individual mitochondrial Ca2+ recording, we discovered impaired extrusion kinetics in mitochondria fragmented by both Drp1 and Bβ2 overexpression. Ca2+ uptake was comparable to that of control. Extreme elongation of mitochondria via dominant negative Drp1-K38A enhanced recovery. Understanding these observations, however, requires knowledge of the mitochondrial Ca2+ buffering mechanism. Mitochondrial uptake candidates include MCU and ccdc109b. Our neuronal characterization of MCU confirms a role in mitochondrial Ca2+ buffering, but not a requirement; other components must be involved. Ccdc109b remains an inconclusive candidate, but may be an important regulator of MCU. Mitochondrial efflux transporters include Letm1 and NCLX. Though Letm1 observations are hindered by control artifact, preliminary evidence supports a role in extrusion. The role of NCLX is complicated by possible tissue specificity. Functional expression experiments utilizing Na+ free Li+ external solution suggests absence of NCLX in hippocampal neurons; DRG neurons were capable of Li+ exchange. The above observations confirm the significance of mitochondrial Ca2+ extrusion in neuronal survival. Understanding the mechanisms and regulation of mitochondrial Ca2+ transport has the potential to provide novel therapeutic targets in pathologies of excitotoxic etiology.

Calcium

Excitotoxicity

Fission

Fusion

Mitochondria

Uniporter

Pharmacology

Mitochondrial Calcium Uptake: LETM1 and MICU1 Are Mitochondrial Proteins That Regulate Mitochondrial Calcium Homeostasis and Cellular Bioenergetics

Doonan, Patrick John

January 2012

Mitochondrial calcium (Ca2+) uptake has been studied for over five decades, with crucial insights into its underlying mechanisms enabled by development of the chemi-osmotic hypothesis and appreciation of the considerable voltage present across the inner mitochondrial membrane (ΔΨm) generated by proton pumping by the respiratory chain (Carafoli, 1987; Nicholls, 2005). However, the molecules that regulate mitochondrial Ca2+ uptake have only recently been identified (Jiang et. al., 2009; Perocchi et. al., 2010) and further work was needed to clarify how these molecules regulate mitochondrial Ca2+ uptake. Leucine Zipper EF hand containing Transmembrane Protein 1 (LETM1) acts as a regulator of mitochondrial Ca2+ uptake distinct from the mitochondrial Ca2+ uniporter (MCU) pathway (Jiang et. al., 2009). However, a controversy exists regarding the function of LETM1 (Nowikovsky et. al., 2004). Therefore, I asked if LETM1 played a role in mitochondrial Ca2+ uptake and if LETM1 regulated cellular bioenergetics and basal autophagy. To further characterize mitochondrial calcium uptake, we asked how Mitochondrial Calcium Uptake 1 (MICU1) regulates MCU activity by quantifying basal mitochondrial Ca2+ and MCU uptake rates in MICU1 ablated cells. The following work characterizes the molecules that regulate mitochondrial Ca2+ uptake and their mechanistic function on decoding calcium signals. Since LETM1 is the Ca2+/H+ antiporter, I hypothesize that alterations in LETM1 expression and activity will decrease mitochondrial Ca2+ uptake and will result in impaired mitochondrial bioenergetics. As a regulator of free intracellular Ca2+, mitochondrial Ca2+ uptake and the orchestra of its regulatory molecules have been implicated in many human diseases. Mitochondria act both upstream by regulating cytosolic Ca2+ concentration and as downstream effectors that respond to Ca2+ signals. Recently, LETM1 was proposed as a mitochondrial Ca2+/H+ antiporter (Jiang et. al., 2009); however characterization of the functional role of LETM1-mediated Ca2+ transfer remained unstudied. Therefore the specific aims of this project were to determine how LETM1 regulates Ca2+ homeostasis and bioenergetics under physiological settings. Secondly, this project aimed to characterize how LETM1-dependent Ca2+ signaling regulates ROS production and autophagy. The data presented here confirmed that LETM1 knockdown significantly impairs mitochondrial Ca2+ uptake. Furthermore, in-depth approaches including either deletion of EF-hand or mutation of critical EF-hand residues (D676A D688KLETM1) impaired histamine (GPCR agonist)-induced mitochondrial Ca2+ uptake. Knockdown of LETM1 resulted in bioenergetic collapse and promoted LC3-positive multilamellar vesicle formation, indicative of autophagy induction. Interestingly, knockdown of LETM1 significantly reduced complex IV but not complex I and complex II-mediated oxygen consumption rate (OCR). In contrast, cellular NADH and mitochondrial membrane potential (ΔΨm) were unaltered in both control and LETM1 knockdown cells. LETM1 has been implicated in formation of the supercomplexes of the electron transport chain (Tamai et. al., 2008). In support, these studies show that LETM1 knockdown results in increased reactive oxygen species (ROS) production. These results for the first time demonstrate that LETM1 controls cellular bioenergetics through regulation of mitochondrial Ca2+ and ROS. MICU1 was identified as an essential regulator of the mitochondrial Ca2+ uniporter (Perocchi et. al., 2010). Therefore, this project specifically aimed to determine how MICU1 regulates the mitochondrial Ca2+ uniporter. Interestingly, the data presented here suggest that MICU1 is not necessary for uniporter activity. Instead, loss of MICU1 caused mitochondria to constitutively load Ca2+ at rest which resulted in a host of cellular phenotypes. This result led to further questions on how MICU1 knockdown affects cellular bioenergetics and if MICU1 is essential for cell survival under stress. MICU1 ablation influenced pyruvate dehydrogenase activity and ROS production. Subsequent investigations demonstrated that increased basal ROS left cells poised to ceramide-induced cell death thereby suggesting the role of MICU1 in cell survival. Collectively, the data presented here show that MICU1 is necessary to control constitutive mitochondrial Ca2+ uptake during rest. This work demonstrates that LETM1 regulates a distinct mode of mitochondrial Ca2+ uptake pathway whereas MICU1 controls mitochondrial Ca2+ uniporter activity. Further studies are required to uncover the potential role of these two mitochondrial-resident Ca2+ regulators in health and disease. / Biochemistry

Biochemistry

Biology, Molecular

Calcium

Letm1

Micu1

Mitochondria

Mitochondria Calcium Uniporter

Uniporter

Molecular mechanisms and functions of mitochondrial calcium transport in neurons

Rysted, Jacob Eugene

01 December 2018

During neuronal activity mitochondria alter cytosolic Ca2+ signaling by buffering then releasing Ca2+ in the cytosol. This calcium transport by mitochondria affects the amplitude, duration, and spacial profile of the Ca2+ signal in the cytosol of neurons. This buffering by mitochondria has been shown to affect a variety of neuronal functions including: neurotransmission, gene expression, cell excitability, and cell death. Recently, researchers discovered that the protein CCDC109A (mitochondrial Ca2+ uniporter) was the protein responsible for mitochondrial Ca2+ uptake. Using a genetic knockout (KO) mouse model for the mitochondrial Ca2+ uniporter (MCU) my research investigated the role of MCU in neuronal function. In cultured central and peripheral neurons, MCU-KO significantly reduced mitochondrial Ca2+ uptake while significantly increasing the amplitude of the cytosolic Ca2+ signal amplitude. Behaviorally, MCU-KO mice show a small but significant impairment in memory tasks: fear conditioning and Barnes maze. Using a maximal electroshock seizure threshold model of in vivo seizure activity my research found that MCU-KO significantly increases the threshold for maximal seizure activity in mice and significantly reduces seizure severity. In addition to mitochondrial Ca2+ uptake, my research also investigated the mechanisms involved in mitochondrial Ca2+ extrusion. The protein SLC8B1 (SLC24A6, NCLX) is the putative transporter responsible for the Na+/Ca2+ exchange, mitochondrial calcium extrusion. Using genetic NCLX-KO mice, our research found that in neurons NCLX contributes to cytosolic Ca2+ extrusion, but does seem to directly affect mitochondrial Ca2+ extrusion.

calcium

mitochondria

mitochondrial calcium uniporter

NCLX

neuron

Neuroscience and Neurobiology

Characterization of Mitochondrial Calcium Uniporter in Barth Syndrome Models

Hartmann, Magnus

16 June 2020

No description available.

572

Mitochondrial Calcium Uniporter

Barth Syndrome

Especificidades teciduais e de sexo no transporte de Ca2+ por mitocôndrias isoladas = avaliações em condições que impedem a transição de permeabilidade = Tissue and sex especifities in the Ca2+ handling by isolated mitochondria: evaluations under conditions avoiding the permeability transition / Tissue and sex especifities in the Ca2+ handling by isolated mitochondria : evaluations under conditions avoiding the permeability transition

Chweih, Hanan, 1990-

27 August 2018

Orientadores: Tiago Rezende Figueira, Roger Frigério Castilho / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-27T03:45:16Z (GMT). No. of bitstreams: 1 Chweih_Hanan_M.pdf: 1684363 bytes, checksum: edae156378f90e7315bca30c16544071 (MD5) Previous issue date: 2015 / Resumo: Algumas das características das mitocôndrias, incluindo as suas funções de transporte de Ca2+, podem apresentar dimorfismo sexual e especificidades teciduais. No entanto, as mensurações do transporte de Ca2+ em mitocôndrias isoladas estão sujeitas a artefatos secundários a abertura do poro de transição de permeabilidade mitocondrial (PTP) induzido pelo acúmulo excessivo de Ca2+ nesta organela. Neste estudo, o objetivo inicial foi avaliar se a inibição do PTP pela ciclosporina A (CsA) afeta a mensuração de diversas variáveis que descrevem o transporte de Ca2+por mitocôndrias isoladas de fígado de rato. Os resultados obtidos indicam que as concentrações de estado estável do Ca2+ externo a mitocôndria e as taxas deefluxo mitocondrial de Ca2+através de trocadores seletivos foram superestimados em até 4 vezes quando o PTP não foi inibido farmacologicamente pela CsA. O objetivo subsequente foi analisar o transporte de Ca2+ em mitocôndrias isoladas de fígado, de músculo esquelético, de coração e de cérebro de ratos machos e fêmeas sob condições experimentais específicas (i.e. meio de incubação contendo inibidores TPM, substratos energéticos ligados a NAD e níveis relevantes de Ca2+, Mg2+e Na+). Os dados indicaram que a taxa de influxo de Ca2+em mitocôndrias de fígado foi ~4 vezes superior a dos outros tecidos, as quais foram semelhantes entre si. Em contrapartida, as taxas de efluxo de Ca2+ apresentaram uma maior diversidade entre tecidos, especialmente na presença de Na+. Curiosamente, o efluxo de Ca2+na ausência de Na+foi significativamente mais elevado nas mitocôndrias cardíacas (~4nmol/mg/min) em relação às taxas observadas nos outros tecidos, contrariando a concepção de que o efluxo de Ca2+de mitocôndrias de coração é dependente, quase que exclusivamente, de um trocador que requer Na+. A especificidade em relação ao sexo só foi observada em dois índices relacionados a homeostase mitocondrial de Ca2+(i.e. cinética geral normalizada da captação de Ca2+ e a concentração de estado estável do Ca2+ externo a mitocôndria) em mitocôndrias isoladas de coração (mais lentos ou maiores na fêmea) e na respiração estimulada por ADP em mitocôndrias de fígado (~20% maior na fêmea). O presente estudo demonstrou a importância metodológica de se prevenir a abertura do PTP para a análise das propriedades e da variabilidade fisiológica do transporte de Ca2+por mitocôndrias isoladas. Adicionalmente, concluímos que sob as condições experimentais aqui utilizadas, o efluxo de Ca2+ mitocondrial apresenta grandes especificidades teciduais e que alguns achados desafiam conceitos estabelecidos em estudos anteriores sob condições arguivelmente menos controladas / Abstract: The characteristics of mitochondria, including their Ca2+ transport functions, may exhibit tissue specificity and sex dimorphism. Because the measurements of the Ca2+ handling by isolated mitochondria may be biased by dysfunction secondary to Ca2+-induced mitochondrial permeability transition (MPT) pore opening, this study evaluates the extent to which MPT inhibition by cyclosporine-A affects the measurement of Ca2+ transport in isolated rat liver mitochondria. The results indicate that the steady-state levels of external Ca2+ and the rates of mitochondrial Ca2+ efflux through the selective pathways can be overestimated by up to 4-fold if MPT pore opening is not prevented. Then, we analyzed the Ca2+ transport in isolated mitochondria from the liver, skeletal muscle, heart and brain of male and female rats under incubation conditions containing MPT inhibitors, NAD-linked substrates and relevant levels of free Ca2+, Mg2+ and Na+. Except for the liver mitochondria displaying values4-fold higher, the Ca2+ influx rates were similar among the other tissues. In contrast, the Ca2+ efflux rates exhibited more tissue diversity, especially in the presence of Na+. Interestingly, the Na+-independent Ca2+ efflux was highest in the heart mitochondria (~4 nmol/mg/min), thus challenging the view that heart mitochondrial Ca2+ efflux relies almost exclusively on a Na+-dependent pathway. Sex specificity was only observed in two kinetic indexes (i.e. the normalized overall kinetics of Ca2+ uptake and the steady-state levels of external Ca2+) of heart mitochondrial Ca2+ homeostasis (slower or higher in female)and in the ADP-stimulated respiration of liver mitochondria (~20% higher in females). The present study shows the methodological importance of preventing MPT when measuring the properties and the physiological variability of the Ca2+ handling by isolated mitochondria. Moreover, we conclude that mitochondrial Ca2+ efflux exhibits great tissue specificity under our conditions, which may challenge some concepts raised in previous studies that employed experimental conditions that are arguably not well controlled / Mestrado / Fisiopatologia Médica / Mestra em Ciências

Homeostase

Troca iônica

Uniporter mitocondrial de cálcio

Mitochondrial calcium uniporter

Mitochondrial permeability transition

Homeostasis

Ion exchange

Characterizing the Role of the Mitochondrial Calcium Uniporter Channel in Vascular Endothelial Mechanotransduction

Patel, Akshar

January 2022

No description available.

Biomedical Engineering

Cellular Biology

Vascular Mechanotransduction

Shear Stress

Calcium Signaling

Atherosclerosis

Endothelial Cell Dysfunction

Mitochondrial Calcium Uniporter

Hemodynamic Forces