Abstract P334: Biophysical Properties Of A Novel Mitochondrial Large Ubiquitous Non-selective Amiloride Sensitive (luna) Current

2021 ◽  
Vol 129 (Suppl_1) ◽  
Author(s):  
Enrique Balderas-Angeles ◽  
Thirupura Shankar ◽  
Anthony Balynas ◽  
Xue Yin ◽  
Dipayan Chaudhuri
Keyword(s):  
Ion Channels ◽  
Divalent Cations ◽  
Pressure Overload ◽  
Atp Synthesis ◽  
Intermembrane Space ◽  
Inner Mitochondrial Membrane ◽  
Patch Clamp Technique ◽  
Transport Chain ◽  
The Matrix ◽  
Established Cell

Inner mitochondrial membrane (IMM) ion channels and transporters account for communication of the matrix with the intermembrane space (IMS) and the cytosol. Transport of solutes and ions is keep under strict regulation mainly because small changes in solute concentrations could generate changes in mitochondrial volume or membrane potential (ΔΨ m ), interrupting ATP synthesis and leading to mitochondrial damage. The list of recently discovered mitochondrial ion channels has been growing in the past decades. In this work, using the patch-clamp technique we observed the activity of a novel mitochondrial current, named here LUNA current, in mitoplasts (IMM striped of outer membrane) from mouse liver, spleen, brain and heart, as well as established cell lines. LUNA is a novel non-selective cation current (K + >Na + >NMDG + >H + ) active at depolarized membrane potentials. The basal activity of whole-mitoplast LUNA currents from wild type mice hearts changed from 445±106 pA/pF to 1232±287 pA/pF upon chelation of external divalent cations (Ca 2+ and Mg 2+ ). Moreover, the activity of LUNA is independent of the mitochondrial Ca 2+ uniporter and of the non-selective reactive oxygen species modulator channel (ROMO1). In the heart, the activity of LUNA was enhanced in both the Tfam -KO mice, which have impaired electron transport chain (ETC) activity and are a model for mitochondrial cardiomyopathies, and mice with cardiac pressure overload due to transverse aortic constriction (TAC) compared to sham-operated hearts (729±197; n=7 vs 283±137 pA/pF). LUNA current is reversibly inhibited by amiloride with no sensitivity to the vast majority of common K + , Na + and Ca 2+ channels and ETC inhibitors. The molecular identity of mitochondrial LUNA current remains to be determined.

scholarly journals Coupled transmembrane mechanisms control MCU-mediated mitochondrial Ca2+uptake

2020 ◽  
Vol 117 (35) ◽  
pp. 21731-21739 ◽  
Author(s):  
Horia Vais ◽  
Riley Payne ◽  
Usha Paudel ◽  
Carmen Li ◽  
J. Kevin Foskett
Keyword(s):  
Mitochondrial Membrane ◽  
Permeability Transition Pore ◽  
Permeability Transition ◽  
Regulatory Mechanisms ◽  
Intermembrane Space ◽  
Channel Activity ◽  
Inner Mitochondrial Membrane ◽  
Energy Demands ◽  
Transport Chain ◽  
The Matrix

Ca2+uptake by mitochondria regulates bioenergetics, apoptosis, and Ca2+signaling. The primary pathway for mitochondrial Ca2+uptake is the mitochondrial calcium uniporter (MCU), a Ca2+-selective ion channel in the inner mitochondrial membrane. MCU-mediated Ca2+uptake is driven by the sizable inner-membrane potential generated by the electron-transport chain. Despite the large thermodynamic driving force, mitochondrial Ca2+uptake is tightly regulated to maintain low matrix [Ca2+] and prevent opening of the permeability transition pore and cell death, while meeting dynamic cellular energy demands. How this is accomplished is controversial. Here we define a regulatory mechanism of MCU-channel activity in which cytoplasmic Ca2+regulation of intermembrane space-localized MICU1/2 is controlled by Ca2+-regulatory mechanisms localized across the membrane in the mitochondrial matrix. Ca2+that permeates through the channel pore regulates Ca2+affinities of coupled inhibitory and activating sensors in the matrix. Ca2+binding to the inhibitory sensor within the MCU amino terminus closes the channel despite Ca2+binding to MICU1/2. Conversely, disruption of the interaction of MICU1/2 with the MCU complex disables matrix Ca2+regulation of channel activity. Our results demonstrate how Ca2+influx into mitochondria is tuned by coupled Ca2+-regulatory mechanisms on both sides of the inner mitochondrial membrane.

scholarly journals Protein sorting between mitochondrial membranes specified by position of the stop-transfer domain.

1988 ◽  
Vol 106 (5) ◽  
pp. 1499-1505 ◽  
Author(s):  
M Nguyen ◽  
A W Bell ◽  
G C Shore
Keyword(s):  
G Protein ◽  
Simple Extension ◽  
Intermembrane Space ◽  
Mitochondrial Membranes ◽  
Inner Mitochondrial Membrane ◽  
The Matrix ◽  
Targeting Signal ◽  
Vesicular Stomatitis ◽  
Matrix Precursor ◽  
Identical Fashion

Recently, we fused a matrix-targeting signal to a large fragment of vesicular stomatitis virus G protein, which contains near its COOH-terminus a well-characterized endoplasmic reticulum (ER) stop-transfer sequence; the hybrid G protein was sorted to the inner mitochondrial membrane (Nguyen, M., and G. C. Shore. 1987. J. Biol. Chem. 262:3929-3931). Here, we show that the 19 amino acid G stop-transfer domain functions in an identical fashion when inserted toward the COOH-terminus of an otherwise normal matrix precursor protein, pre-ornithine carbamyl transferase; after import, the mutant protein was found anchored in the inner membrane via the stop-transfer sequence, with its NH2 terminus facing the matrix and its short COOH-terminal tail located in the intermembrane space. However, when the G stop-transfer sequence was placed near the NH2 terminus, the protein was inserted into the outer membrane, in the reverse orientation (NH2 terminus facing out, with a large COOH-terminal fragment located in the intermembrane space). These observations for mitochondrial topogenesis can be explained by a simple extension of existing models for ER sorting.

scholarly journals Permeation of both cations and anions through a single class of ATP-activated ion channels in developing chick skeletal muscle.

1990 ◽  
Vol 95 (4) ◽  
pp. 569-590 ◽  
Author(s):  
S A Thomas ◽  
R I Hume
Keyword(s):  
Skeletal Muscle ◽  
Ion Channels ◽  
Divalent Cations ◽  
Reversal Potential ◽  
Noise Spectrum ◽  
Chloride Ions ◽  
Simultaneous Increase ◽  
Anion Channels ◽  
Patch Clamp Technique ◽  
Single Class

Micromolar concentrations of extracellular adenosine 5'-triphosphate (ATP) elicit a rapid excitatory response in developing chick skeletal muscle. Excitation is the result of a simultaneous increase in membrane permeability to sodium, potassium, and chloride ions. In the present study we quantify the selectivity of the ATP response, and provide evidence that a single class of ATP-activated ion channels conducts both cations and anions. Experiments were performed on myoballs using the whole-cell patch-clamp technique. We estimated permeability ratios by measuring the shift in reversal potential when one ion was substituted for another. We found that monovalent cations, divalent cations, and monovalent anions all permeate the membrane during the ATP response, and that there was only moderate selectivity between many of these ions. Calcium was the most permeant ion tested. To determine if ATP activates a single class of channels that conducts both cations and anions, or if ATP activates separate classes of cation and anion channels, we analyzed the fluctuations about the mean current induced by ATP. Ionic conditions were arranged so that the reversal potential for cations was +50 mV and the reversal potential for anions was -50 mV. Under these conditions, if ATP activates a single class of channels, ATP should not evoke an increase in noise at the reversal potential of the ATP current. However, if ATP activates separate classes of cation and anion channels, ATP should evoke a significant increase in noise at the reversal potential of the ATP current. At both +40 and -50 mV ATP elicited a clear increase in noise, but at the reversal potential of the ATP current (-5 mV), no increase in noise above background was seen. These results indicate that there is only a single class of excitatory ATP-activated channels, which do not select by charge. Based on analysis of the noise spectrum, the conductance of individual channels is estimated to be 0.2-0.4 pS.

scholarly journals Mutational Analysis of the Saccharomyces cerevisiae Cytochrome c Oxidase Assembly Protein Cox11p

2006 ◽  
Vol 5 (3) ◽  
pp. 568-578 ◽  
Author(s):  
Graham S. Banting ◽  
D. Moira Glerum
Keyword(s):  
Hydrogen Peroxide ◽  
Cytochrome Oxidase ◽  
Solution Structure ◽  
Sinorhizobium Meliloti ◽  
Mutational Analysis ◽  
Intermembrane Space ◽  
Copper Binding ◽  
Inner Mitochondrial Membrane ◽  
The Matrix

ABSTRACT Cox11p is an integral protein of the inner mitochondrial membrane that is essential for cytochrome c oxidase assembly. The bulk of the protein is located in the intermembrane space and displays high levels of evolutionary conservation. We have analyzed a collection of site-directed and random cox11 mutants in an effort to further define essential portions of the molecule. Of the alleles studied, more than half had no apparent effect on Cox11p function. Among the respiration deficiency-encoding alleles, we identified three distinct phenotypes, which included a set of mutants with a misassembled or partially assembled cytochrome oxidase, as indicated by a blue-shifted cytochrome aa 3 peak. In addition to the shifted spectral signal, these mutants also display a specific reduction in the levels of subunit 1 (Cox1p). Two of these mutations are likely to occlude a surface pocket behind the copper-binding domain in Cox11p, based on analogy with the Sinorhizobium meliloti Cox11 solution structure, thereby suggesting that this pocket is crucial for Cox11p function. Sequential deletions of the matrix portion of Cox11p suggest that this domain is not functional beyond the residues involved in mitochondrial targeting and membrane insertion. In addition, our studies indicate that Δcox11, like Δsco1, displays a specific hypersensitivity to hydrogen peroxide. Our studies provide the first evidence at the level of the cytochrome oxidase holoenzyme that Cox1p is the in vivo target for Cox11p and suggest that Cox11p may also have a role in the response to hydrogen peroxide exposure.

scholarly journals The mitochondrial carrier pathway transports non-canonical substrates with an odd number of transmembrane segments

BMC Biology ◽  
2020 ◽  
Vol 18 (1) ◽  
Author(s):  
Heike Rampelt ◽  
Iva Sucec ◽  
Beate Bersch ◽  
Patrick Horten ◽  
Inge Perschil ◽  
...  
Keyword(s):  
Intermembrane Space ◽  
Inner Mitochondrial Membrane ◽  
Inner Membrane ◽  
Mitochondrial Carrier ◽  
Transmembrane Segments ◽  
Mitochondrial Inner Membrane ◽  
N Terminus ◽  
The Matrix ◽  
Mitochondrial Carrier Family ◽  
Mitochondrial Intermembrane Space

Abstract Background The mitochondrial pyruvate carrier (MPC) plays a central role in energy metabolism by transporting pyruvate across the inner mitochondrial membrane. Its heterodimeric composition and homology to SWEET and semiSWEET transporters set the MPC apart from the canonical mitochondrial carrier family (named MCF or SLC25). The import of the canonical carriers is mediated by the carrier translocase of the inner membrane (TIM22) pathway and is dependent on their structure, which features an even number of transmembrane segments and both termini in the intermembrane space. The import pathway of MPC proteins has not been elucidated. The odd number of transmembrane segments and positioning of the N-terminus in the matrix argues against an import via the TIM22 carrier pathway but favors an import via the flexible presequence pathway. Results Here, we systematically analyzed the import pathways of Mpc2 and Mpc3 and report that, contrary to an expected import via the flexible presequence pathway, yeast MPC proteins with an odd number of transmembrane segments and matrix-exposed N-terminus are imported by the carrier pathway, using the receptor Tom70, small TIM chaperones, and the TIM22 complex. The TIM9·10 complex chaperones MPC proteins through the mitochondrial intermembrane space using conserved hydrophobic motifs that are also required for the interaction with canonical carrier proteins. Conclusions The carrier pathway can import paired and non-paired transmembrane helices and translocate N-termini to either side of the mitochondrial inner membrane, revealing an unexpected versatility of the mitochondrial import pathway for non-cleavable inner membrane proteins.

Abstract 995: Blockade Of Electron Transport Preserves The Contents Of Bcl-2 And Cytochrome c In Subsarcolemmal Mitochondria During Ischemia

Circulation ◽  
2007 ◽  
Vol 116 (suppl_16) ◽  
Author(s):  
Qun Chen ◽  
Edward J Lesnefsky
Keyword(s):  
Electron Transport ◽  
Outer Membrane ◽  
Rabbit Heart ◽  
Intermembrane Space ◽  
Inner Mitochondrial Membrane ◽  
Complex Iv ◽  
Inner Membrane ◽  
Transport Chain ◽  
Subsarcolemmal Mitochondria

Cardiac ischemia decreases the rate of oxidative phosphorylation (OXPHOS) and the contents of cardiolipin and cytochrome c (CYTc) in subsarcolemmal mitochondria (SSM) in the isolated rabbit heart. CYTc release first requires damage to the inner mitochondrial membrane to delocalize CYTc to the intermembrane space, followed by breach of the outer membrane. The decrease in cardiolipin content allows CYTc detachment from the inner membrane. It is still unclear how CYTc passes the outer membrane for release into cytosol. We propose that ischemia increases outer-membrane leakage by depletion of bcl-2 content, and that oxidants generated by the electron transport chain (ETC) during ischemia favor bcl-2 depletion. We used blockade of the proximal ETC at complex I during ischemia with amobarbital (AMO) to test the role of ETC during ischemia. Langendorff perfused rabbit hearts were treated with AMO (2.5 mM for 1 min) or vehicle immediately before 30 min global ischemia (37°C). Time controls were perfused for 45 min. SSM were isolated at the end of ischemia. CYTc content (reduced minus oxidized spectra), OXPHOS and bcl-2 (western blotting) were measured. Ischemia decreased OXPHOS with TMPD-ascorbate as substrate (electron donor to complex IV via CYTc) and the contents of CYTc and bcl-2. In contrast, AMO preserves OXPHOS, CYTc and bcl-2. Thus, blockade of electron transport preserves bcl-2 content during ischemia with enhanced CYTc retention by SSM. The ETC contributes to mitochondrial damage during ischemia, depleting cardiolipin in the inner membrane and bcl-2 in the outer membrane favoring the two steps required for release of CYTc from mitochondria during ischemia and reperfusion.

nde1 deletion improves mitochondrial DNA maintenance in Saccharomyces cerevisiae coenzyme Q mutants

2013 ◽  
Vol 449 (3) ◽  
pp. 595-603 ◽  
Author(s):  
Fernando Gomes ◽  
Erich B. Tahara ◽  
Cleverson Busso ◽  
Alicia J. Kowaltowski ◽  
Mario H. Barros
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Mitochondrial Dna ◽  
Coenzyme Q ◽  
Intermembrane Space ◽  
Inner Mitochondrial Membrane ◽  
Yeast Strains ◽  
The Matrix ◽  
Nadh Dehydrogenases ◽  
Genetically Manipulated ◽  
Dna Maintenance

Saccharomyces cerevisiae has three distinct inner mitochondrial membrane NADH dehydrogenases mediating the transfer of electrons from NADH to CoQ (coenzyme Q): Nde1p, Nde2p and Ndi1p. The active site of Ndi1p faces the matrix side, whereas the enzymatic activities of Nde1p and Nde2p are restricted to the intermembrane space side, where they are responsible for cytosolic NADH oxidation. In the present study we genetically manipulated yeast strains in order to alter the redox state of CoQ and NADH dehydrogenases to evaluate the consequences on mtDNA (mitochondrial DNA) maintenance. Interestingly, nde1 deletion was protective for mtDNA in strains defective in CoQ function. Additionally, the absence of functional Nde1p promoted a decrease in the rate of H2O2 release in isolated mitochondria from different yeast strains. On the other hand, overexpression of the predominant NADH dehydrogenase NDE1 elevated the rate of mtDNA loss and was toxic to coq10 and coq4 mutants. Increased CoQ synthesis through COQ8 overexpression also demonstrated that there is a correlation between CoQ respiratory function and mtDNA loss: supraphysiological CoQ levels were protective against mtDNA loss in the presence of oxidative imbalance generated by Nde1p excess or exogenous H2O2. Altogether, our results indicate that impairment in the oxidation of cytosolic NADH by Nde1p is deleterious towards mitochondrial biogenesis due to an increase in reactive oxygen species release.

scholarly journals Regulation of COX Assembly and Function by Twin CX9C Proteins—Implications for Human Disease

Cells ◽  
2021 ◽  
Vol 10 (2) ◽  
pp. 197
Author(s):  
Stephanie Gladyck ◽  
Siddhesh Aras ◽  
Maik Hüttemann ◽  
Lawrence I. Grossman
Keyword(s):  
Electron Transport ◽  
Cytochrome C ◽  
Atp Synthase ◽  
Protein Interactions ◽  
Human Disease ◽  
Electron Transport Chain ◽  
Intermembrane Space ◽  
Protein Protein Interactions ◽  
Inner Mitochondrial Membrane ◽  
Transport Chain

Oxidative phosphorylation is a tightly regulated process in mammals that takes place in and across the inner mitochondrial membrane and consists of the electron transport chain and ATP synthase. Complex IV, or cytochrome c oxidase (COX), is the terminal enzyme of the electron transport chain, responsible for accepting electrons from cytochrome c, pumping protons to contribute to the gradient utilized by ATP synthase to produce ATP, and reducing oxygen to water. As such, COX is tightly regulated through numerous mechanisms including protein–protein interactions. The twin CX9C family of proteins has recently been shown to be involved in COX regulation by assisting with complex assembly, biogenesis, and activity. The twin CX9C motif allows for the import of these proteins into the intermembrane space of the mitochondria using the redox import machinery of Mia40/CHCHD4. Studies have shown that knockdown of the proteins discussed in this review results in decreased or completely deficient aerobic respiration in experimental models ranging from yeast to human cells, as the proteins are conserved across species. This article highlights and discusses the importance of COX regulation by twin CX9C proteins in the mitochondria via COX assembly and control of its activity through protein–protein interactions, which is further modulated by cell signaling pathways. Interestingly, select members of the CX9C protein family, including MNRR1 and CHCHD10, show a novel feature in that they not only localize to the mitochondria but also to the nucleus, where they mediate oxygen- and stress-induced transcriptional regulation, opening a new view of mitochondrial-nuclear crosstalk and its involvement in human disease.

scholarly journals Localized Proteotoxic Stress in Mitochondrial Intermembrane Space and Matrix Elicits Sub-compartment Specific Response Pathways Governed by Unique Modulators

2020 ◽  
Author(s):  
Kannan Boosi Narayana Rao ◽  
Pratima Pandey ◽  
Rajasri Sarkar ◽  
Asmita Ghosh ◽  
Shemin Mansuri ◽  
...  
Keyword(s):  
Stress Response ◽  
Cellular Response ◽  
Protein Quality ◽  
Atp Synthesis ◽  
Specific Response ◽  
Intermembrane Space ◽  
Matrix Stress ◽  
Proteotoxic Stress ◽  
Tom Complex ◽  
The Matrix

AbstractThe complex double-membrane architecture of mitochondria is essential for its ATP synthesis function and divides the organelle into two sub-mitochondrial compartments, inter-membrane space (IMS) and matrix. The folding environments of IMS and matrix are significantly different owing to its dissimilar oxido-reductive environments and distinctly divergent protein quality control (PQC) machineries. Here, by inducing proteotoxic stress restricted to IMS or matrix by targeting three different stressor proteins, we show that the cellular response to IMS or matrix-localized misfolding stress is distinct and unique. IMS and matrix stress response pathways are quite effective in combatting stress despite significant stress-induced alteration in mitochondrial phenotypes. IMS misfolding stress leads to specific upregulation of IMS chaperones and components of TOM complex while matrix chaperones and cytosolic PQC components are upregulated during matrix stress. Notably, the amplitude of upregulation of mitochondrial chaperones is not overwhelming. We report that cells respond to mitochondrial stress through an adaptive mechanism by adjourning mitochondrial respiration while upregulating glycolysis as a compensatory pathway. We show that subunits of TOM complex act as specific modulators of IMS-stress response while Vms1 precisely modulates the matrix stress response.

scholarly journals Strongly coupled transmembrane mechanisms control MCU-mediated mitochondrial Ca2+ uptake

2020 ◽  
Author(s):  
Horia Vais ◽  
Riley Payne ◽  
Carmen Li ◽  
J. Kevin Foskett
Keyword(s):  
Mitochondrial Membrane ◽  
Permeability Transition Pore ◽  
Permeability Transition ◽  
Regulatory Mechanisms ◽  
Intermembrane Space ◽  
Channel Activity ◽  
Inner Mitochondrial Membrane ◽  
Strongly Coupled ◽  
Energy Demands ◽  
The Matrix

Ca2+ uptake by mitochondria regulates bioenergetics, apoptosis, and Ca2+ signaling. The primary pathway for mitochondrial Ca2+ uptake is the mitochondrial calcium uniporter (MCU), a Ca2+-selective ion channel in the inner mitochondrial membrane. MCU-mediated Ca2+ uptake is driven by the sizable inner-membrane potential generated by the electron-transport chain. Despite the large thermodynamic driving force, mitochondrial Ca2+ uptake is tightly regulated to maintain low matrix [Ca2+] and prevent opening of the permeability transition pore and cell death, while meeting dynamic cellular energy demands. How this is accomplished is controversial. Here we define a regulatory mechanism of MCU-channel activity in which cytoplasmic Ca2+ regulation of intermembrane space-localized MICU1/2 is controlled by strongly-coupled Ca2+-regulatory mechanisms localized across the membrane in the mitochondrial matrix. Ca2+ that permeates through the channel pore regulates Ca2+ affinities of coupled inhibitory and activating sensors in the matrix. Ca2+ binding to the inhibitory sensor within the MCU amino-terminus closes the channel despite Ca2+ binding to MICU1/2. Conversely, disruption of the interaction of MICU1/2 with the MCU complex abolishes matrix Ca2+ regulation of channel activity. Our results demonstrate how Ca2+ influx into mitochondria is tuned by coupled Ca2+-regulatory mechanisms on both sides of the inner mitochondrial membrane.

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