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| | == Overview == | | == Overview == |
| - | The mitochondrial calcium uniporter (MCU) complex is the main source of entry for [https://en.wikipedia.org/wiki/Calcium calcium] ions into the [https://en.wikipedia.org/wiki/Mitochondrial_matrix mitochondrial matrix] from the [https://en.wikipedia.org/wiki/Mitochondrion#Intermembrane_space intermembrane space]. MCU channels exist in most [https://en.wikipedia.org/wiki/Eukaryote eukaryotic] life, but activity is regulated differently in each [https://en.wikipedia.org/wiki/Clade clade].<ref name="Baradaran">PMID:29995857</ref> The precise identity of the MCU wasn't discovered until 2011 and was discovered using a combination of [https://en.wikipedia.org/wiki/Nuclear_magnetic_resonance_spectroscopy NMR spectroscopy], [https://en.wikipedia.org/wiki/Cryogenic_electron_microscopy Cryoelectron microscopy], and [https://en.wikipedia.org/wiki/X-ray_crystallography x-ray crystallography].<ref name="Woods">PMID:31869674</ref> [https://en.wikipedia.org/wiki/Cryogenic_electron_microscopy Cryoelectron microscopy] (Cryo-EM) was instrumental in elucidating the complete structure of the MCU complex, which subsequently provides a structural framework for understanding the mechanism by which the MCU functions.<ref name="Giorgi" /> Prior modeling of the structure was difficult because it has no apparent sequence similarity to other ion channels.<ref name="Baradaran"/> However, like other ion channels, the MCU is highly selective and efficient. The MCU has the ability to only allow calcium ions into the mitochondrial matrix at a rate of 5,000,000 ions per second, even though [https://en.wikipedia.org/wiki/Potassium potassium] ions are over 100,000 times more abundant in the intermembrane space.<ref name="Baradaran"/> | + | The mitochondrial calcium uniporter (MCU) complex is the main source of entry for [https://en.wikipedia.org/wiki/Calcium calcium] ions into the [https://en.wikipedia.org/wiki/Mitochondrial_matrix mitochondrial matrix] from the [https://en.wikipedia.org/wiki/Mitochondrion#Intermembrane_space intermembrane space]. MCU channels exist in most [https://en.wikipedia.org/wiki/Eukaryote eukaryotes], but activity is regulated differently in each [https://en.wikipedia.org/wiki/Clade clade].<ref name="Baradaran">PMID:29995857</ref> MCU was definitively assigned in 2011 using a combination of [https://en.wikipedia.org/wiki/Nuclear_magnetic_resonance_spectroscopy NMR spectroscopy], [https://en.wikipedia.org/wiki/Cryogenic_electron_microscopy cryoelectron microscopy], and [https://en.wikipedia.org/wiki/X-ray_crystallography x-ray crystallography].<ref name="Woods">PMID:31869674</ref> Recent [https://en.wikipedia.org/wiki/Cryogenic_electron_microscopy cryoelectron microscopy] (cryo-EM) analysis provides a structural framework for understanding the mechanism for calcium selectivity by the MCU.<ref name="Giorgi" /> Like other ion channels, the MCU is highly selective and efficient, allowing calcium ions into the mitochondrial matrix at a rate of 5,000,000 ions per second, even though [https://en.wikipedia.org/wiki/Potassium potassium] ions are over 100,000 times more abundant in the intermembrane space.<ref name="Baradaran"/> |
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| - | Under resting conditions, the calcium concentration in the mitochondria is about the same as in the [https://en.wikipedia.org/wiki/Cytoplasm cytoplasm], but when stimulated, it can increase calcium concentration 10 to 20-fold.<ref name="Giorgi">PMID:30143745</ref> ([https://en.wikipedia.org/wiki/Mitochondria_associated_membranes Mitochondria-associated ER membranes]) exist between mitochondria and the [https://en.wikipedia.org/wiki/Endoplasmic_reticulum endoplasmic reticulum], the two largest cellular stores of calcium, to facilitate efficient transport of calcium ions.<ref name="Wang">PMID:28882140</ref> The transfer of electrons through [https://en.wikipedia.org/wiki/Electron_transport_chain#Mitochondrial_redox_carriers respiratory complexes I-IV] produces the energy to pump [https://en.wikipedia.org/wiki/Hydrogen_ion hydrogen ions] into the intermembrane space and create the proton [https://en.wikipedia.org/wiki/Electrochemical_gradient electrochemical gradient] potential.<ref name="Giorgi"/> This negative electrochemical potential is the driving force that moves positively charged calcium ions into the mitochondrial matrix.<ref name="Giorgi"/> | + | Under resting conditions, the calcium concentration in the mitochondria is about the same as in the [https://en.wikipedia.org/wiki/Cytoplasm cytoplasm], but when stimulated, mitochondrial calcium concentration increases 10 to 20-fold.<ref name="Giorgi">PMID:30143745</ref> [https://en.wikipedia.org/wiki/Mitochondria_associated_membranes Mitochondria-associated ER membranes] exist between the mitochondria and the [https://en.wikipedia.org/wiki/Endoplasmic_reticulum endoplasmic reticulum] facilitate efficient transport of calcium ions.<ref name="Wang">PMID:28882140</ref> The transfer of electrons through [https://en.wikipedia.org/wiki/Electron_transport_chain#Mitochondrial_redox_carriers respiratory complexes I-IV] produces the energy to pump [https://en.wikipedia.org/wiki/Hydrogen_ion hydrogen ions] into the intermembrane space and establish the proton [https://en.wikipedia.org/wiki/Electrochemical_gradient electrochemical gradient] potential.<ref name="Giorgi"/> This negative electrochemical potential is the driving force that moves positively charged calcium ions into the mitochondrial matrix.<ref name="Giorgi"/> Calcium uptake and efflux must be tightly regulated to controll essential [https://en.wikipedia.org/wiki/Citric_acid_cycle Krebs cycle] enzyme activity, including [http://proteopedia.org/wiki/index.php/Pyruvate_dehydrogenase pyruvate dehydrogenase], [https://en.wikipedia.org/wiki/Oxoglutarate_dehydrogenase_complex α-ketoglutarate dehydrogenase], and [http://proteopedia.org/wiki/index.php/Isocitrate_dehydrogenase isocitrate dehydrogenase], while avoiding calcium overload and [https://en.wikipedia.org/wiki/Apoptosis apoptosis].<ref name="Wang"/> |
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| - | Regulation of the uptake and efflux of calcium is important to increase calcium levels enough to activate certain enzymes, but also avoid calcium overload and [https://en.wikipedia.org/wiki/Apoptosis apoptosis].<ref name="Wang"/> Mitochondrial calcium increases [http://proteopedia.org/wiki/index.php/ATP ATP] production by activating [http://proteopedia.org/wiki/index.php/Pyruvate_dehydrogenase pyruvate dehydrogenase], [https://en.wikipedia.org/wiki/Oxoglutarate_dehydrogenase_complex α-ketoglutarate dehydrogenase], and [http://proteopedia.org/wiki/index.php/Isocitrate_dehydrogenase isocitrate dehydrogenase] in the [https://en.wikipedia.org/wiki/Citric_acid_cycle Krebs cycle].<ref name="Wang"/> Therefore, a deficiency of MCU leads to decreases in associated enzyme activity and of [https://en.wikipedia.org/wiki/Oxidative_phosphorylation oxidative phosphorylation].
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| | ==Mitochondrial Calcium Uniporter Complex== | | ==Mitochondrial Calcium Uniporter Complex== |
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| - | The mitochondrial calcium uniporter complex exists as a large complex (around 480 kDa in humans) made up of both pore-forming and regulatory subunits.<ref name="Wang"/> The MCU is a complex composed of regulatory subunits including mitochondrial calcium uptake (MICU), essential MICU regulator (EMRE), MCU regulatory subunit b (MCUb), and MCU regulator 1 (MCUR1). <ref name="Fan" /> The mitochondrial uptake proteins (MICU1 and MICU2) are regulatory proteins in the MCU complex that exist in the intermembrane space and contain [https://en.wikipedia.org/wiki/EF_hand EF hand domains] for calcium binding to control transport through the channel of the MCU complex.<ref name="Wang"/> When calcium ion concentration in the intermembrane space is low, MICU1 and 2 block the MCU to prevent uptake of calcium.<ref name="Wang"/> In the presence of high calcium concentrations, more calcium binds to these regulatory proteins and they undergo a conformational change to allow calcium ions through the MCU and into the matrix.<ref name="Wang"/> In fact, when calcium levels are below 500 nM, MICU1 can block movement of calcium by itself, calcium levels between 500 nM and 1,500 nM require both MICU1 and MICU2 to block ion entry, and any concentration over 1,500 nM is sufficient for calcium entry.<ref name="Giorgi"/> Another regulatory protein, MCUR1 is a cofactor in the assembly of the [https://en.wikipedia.org/wiki/Electron_transport_chain respiratory chain] rather than an essential part of the uniporter.<ref name="Giorgi"/> Though the MCU is able to take up calcium independently, there are two other pore-forming subunits, the MCUb and the essential MCU regulator (EMRE).<ref name="Wang"/> MCUb is similar to MCU, but certain amino acids differ and make it an inhibitory subunit.<ref name="Wang"/> The EMRE is located in the intermembrane space and connects MICU1 and MICU2 to the MCU.<ref name="Giorgi"/> It also contributes to regulation of calcium intake in the MCU.<ref name="Wang"/> | + | The MCU complex exists as a large complex (around 480 kDa in humans) made up of both pore-forming and regulatory subunits.<ref name="Wang"/> The MCU complex is composed of the MCU as well as regulatory subunits including the mitochondrial calcium uptake proteins MICU1 and MICU2, essential MICU regulator (EMRE), MCU regulatory subunit b (MCUb), and MCU regulator 1 (MCUR1). <ref name="Fan" /> The mitochondrial uptake proteins (MICU1 and MICU2) are intermembrane regulatory proteins that use their [https://en.wikipedia.org/wiki/EF_hand EF hand domains] to grab intermembrane calcium and to control transport through the channel of the MCU.<ref name="Wang"/> When calcium ion concentration in the intermembrane space is low, MICU1 and 2 block the MCU to prevent uptake of calcium.<ref name="Wang"/> In high calcium concentrations, calcium binds to these regulatory proteins and they undergo a conformational change to allow calcium ions through the MCU and into the matrix.<ref name="Wang"/> When calcium levels are below 500 nM, MICU1 can block movement of calcium by itself, calcium levels between 500 nM and 1,500 nM require both MICU1 and MICU2 to block ion entry, and any concentration over 1,500 nM is sufficient for calcium entry.<ref name="Giorgi"/> Another regulatory protein, MCUR1 is a cofactor in the assembly of the [https://en.wikipedia.org/wiki/Electron_transport_chain respiratory chain] rather than an essential part of the uniporter.<ref name="Giorgi"/> Though the MCU is able to take up calcium independently, two other membrane spanning subunits, the MCUb and the essential MCU regulator (EMRE), connect to the MCI and add further regulatory mechanisms.<ref name="Wang"/> MCUb is similar to MCU, but through key amino acid substitutions serves an inhibitory role.<ref name="Wang"/> The EMRE contributes to regulation of calcium intake in the by connecting MICU1 and MICU2 to the MCU.<ref name="Giorgi"/><ref name="Wang"/> |
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| - | [[Image:structure.png|300 px|right|thumb|Figure 1: Structure of mitochondrial calcium uniporter colored by functional domain. The transmembrane domain is highlighted in salmon, the matrix domain in light cyan, coiled-coil domain in dark violet, and the N-terminal domain in slate blue. [https://en.wikipedia.org/wiki/Protein_Data_Bank PDB] [https://www.rcsb.org/structure/6DT0 6DT0]]] | + | [[Image:structure.png|300 px|right|thumb|Figure 1: Structure of mitochondrial calcium uniporter colored by functional domain. The transmembrane domain is highlighted in salmon, the linker domain spanning the mitochondrial matrix in light cyan, coiled-coil domain in dark violet, and the N-terminal domain in slate blue. [https://en.wikipedia.org/wiki/Protein_Data_Bank PDB] [https://www.rcsb.org/structure/6DT0 6DT0]]] |
| | ==MCU Structure== | | ==MCU Structure== |
| - | The <scene name='83/832952/Starting_scene/5'>mitochondrial calcium uniporter (MCU)</scene> is the ion channel component of the complex (Figure 1). The MCU was originally thought to a pentamer of five identical subunits, but based on the structure was shown to exist as four monomers, identical in sequence, arranged and packed together such that they structurally form a <scene name='83/832952/Dimer_of_dimers/5'>dimer of dimers</scene> (Figure 2).<ref name="Woods">PMID:31869674</ref> The MCU protein is composed of a <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene>, a <scene name='83/837230/Coiled_coil/3'>coiled coil domain</scene>, and a <scene name='83/837230/Nterm/2'>N-Terminal Domain</scene> (NTD) (Figure 1).<ref name="Woods"/> The hydrophobic <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene> is located in the ([https://en.wikipedia.org/wiki/Inner_mitochondrial_membrane inner mitochondrial membrane]) and the hydrophilic coiled-coil domain exists in the mitochondrial matrix.<ref name="Baradaran"/> | + | The <scene name='83/832952/Starting_scene/5'>MCU</scene> is the ion channel component of the MCU complex (Figure 1). An NMR structure of an inactive MCU from ''C. elegans'' showed a pentameric arrangement, but the recent crystal and cryo-EM structures of multiple MCUs reaffirmed that active eukaryotic MCU exists as four monomers, identical in sequence, arranged and packed together such that they structurally form a <scene name='83/832952/Dimer_of_dimers/5'>dimer of dimers</scene> in a tetrameric truncated pyramid (Figure 2).<ref name="Woods">PMID:31869674</ref> The MCU protein is composed of a <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene>, a <scene name='83/837230/Coiled_coil/3'>coiled coil domain</scene>, and a <scene name='83/837230/Nterm/2'>N-terminal domain</scene> (NTD) (Figure 1).<ref name="Woods"/> The hydrophobic <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene> is located in the ([https://en.wikipedia.org/wiki/Inner_mitochondrial_membrane inner mitochondrial membrane]) while the hydrophilic coiled-coil domain and NTD are positioned in the mitochondrial matrix.<ref name="Baradaran"/> |
| - | [[Image:Nterm.png|250 px|right|thumb|Figure 2: Symmetry and organization of subunits from looking down into the uniporter from the inner mitochondrial membrane [https://en.wikipedia.org/wiki/Protein_Data_Bank PDB] [https://www.rcsb.org/structure/6DT0 6DT0]]] | + | [[Image:Nterm.png|250 px|right|thumb|Figure 2: Symmetry and organization of MCU dimer of dimers viewed from the inner mitochondrial membrane [https://en.wikipedia.org/wiki/Protein_Data_Bank PDB] [https://www.rcsb.org/structure/6DT0 6DT0]]] |
| | ===Transmembrane Domain=== | | ===Transmembrane Domain=== |
| - | The <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene> is on the inner mitochondrial membrane open to the inner membrane space (Figure 1). The <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene> consists of eight separate helices (TM1 and TM2 from each subunit) that are connected by mostly hydrophobic amino acids in the intermembrane space and has <scene name='83/832952/Starting_scene/5'>four-fold</scene> symmetry (Figure 2).<ref name="Baradaran"/> The small <scene name='83/832952/Selectivity_filter/3'>selectivity filter</scene> pore, highly specific for calcium binding is located in the interior of the bundle of four packed <scene name='83/832952/Tm2/2'>TM2</scene> helices while the four helices of <scene name='83/837230/Transmembrane_1/2'>TM1</scene> surround this TM2 bundle. <scene name='83/837230/Transmembrane_1/2'>TM1</scene> packs tightly against <scene name='83/832952/Tm2/2'>TM2</scene> from the neighboring subunit which conveys a sense of domain-swapping.<ref name="Fan">PMID:29995856</ref> | + | The <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene> is inserted into the inner mitochondrial membrane and opens to the inner membrane space (Figure 1). The <scene name='83/837230/Transmembrane_domain/3'>transmembrane domain</scene> consists of eight separate helices (TM1 and TM2 from each subunit) with <scene name='83/832952/Starting_scene/5'>four-fold</scene> symmetry that are connected by hydrophobic amino acids in the intermembrane space (Figure 2).<ref name="Baradaran"/> The small <scene name='83/832952/Selectivity_filter/3'>selectivity filter</scene> pore, highly specific for calcium binding is located in the interior of the bundle of four packed <scene name='83/832952/Tm2/2'>TM2</scene> helices while the four helices of <scene name='83/837230/Transmembrane_1/2'>TM1</scene> surround this TM2 bundle. <scene name='83/837230/Transmembrane_1/2'>TM1</scene> packs tightly against <scene name='83/832952/Tm2/2'>TM2</scene> from the neighboring subunit which conveys a sense of domain-swapping.<ref name="Fan">PMID:29995856</ref> |
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| | ===Coiled-coil Domain=== | | ===Coiled-coil Domain=== |
| - | Past the transmembrane domain, the N-terminal domains of the <scene name='83/832952/Tm1/2'>TM1</scene> helices extend into the matrix and form coiled-coils with a C-terminal helix.<ref name="Baradaran"/> These "legs" are separated from each other which allows enough space for calcium ions to diffuse out into the matrix.<ref name="Baradaran"/> The <scene name='83/837230/Coiled_coil/3'>coiled coil</scene> domain is the first subsection of the soluble domain, which resides in the inner mitochondrial membrane. The coiled coil functions as the joints of the uniporter, providing flexibility to promote transport of Ca<sup>2+</sup>ions down their concentration gradient.<ref name="Fan" /> When Ca<sup>2+</sup> ions binds to the selectivity pore, the coiled-coil swings approximately 8° around its end near the <scene name='83/837230/Nterm/2'>NTD</scene>. This movement propagates to the top of the transmembrane domain, where the pore is located about 85 Å away. The largest displacement triggered by the movement of the coiled-coil is in the transmembrane domain, where the coil bends 20°, moving the transmembrane domain further apart. The junction between the transmembrane domain and the coiled coil's flexibility can be attributed to the disordered packing between subunits. Subunits A and C adopt different conformations than the B and D subunits, although they superimpose closely.<ref name="Fan" /> The coiled-coil domain is also responsible for assembly of the MCU and is [https://en.wikipedia.org/wiki/Post-translational_modification post-translationally modified].<ref name="Fan"/>
| + | The N-terminal domains of the <scene name='83/832952/Tm1/2'>TM1</scene> helices extend into the matrix and form coiled-coils with a C-terminal helix.<ref name="Baradaran"/> These "legs" are separated from each other which allows enough space for calcium ions to diffuse out into the matrix.<ref name="Baradaran"/> The <scene name='83/837230/Coiled_coil/3'>coiled coil</scene> domain is the first subsection of the soluble domain, which resides in the inner mitochondrial membrane. The coiled coil functions as the joints of the uniporter, providing flexibility to promote transport of Ca<sup>2+</sup>ions down their concentration gradient.<ref name="Fan" /> When Ca<sup>2+</sup> ions binds to the selectivity pore, the coiled-coil swings approximately 8° around its end near the <scene name='83/837230/Nterm/2'>NTD</scene>. This movement propagates to the top of the transmembrane domain, where the pore is located about 85 Å away. The coiled coil's flexibility can be attributed to the disordered packing between subunits. Subunits A and C adopt different conformations than the B and D subunits, although they superimpose closely.<ref name="Fan" /> The coiled-coil domain is also required for proper assembly of the MCU and is [https://en.wikipedia.org/wiki/Post-translational_modification post-translationally modified].<ref name="Fan"/> |
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| | ===N-terminal Domain=== | | ===N-terminal Domain=== |
| - | Finally, each leg ends in a <scene name='83/832952/New_ones/4'>non-translated domain</scene> (NTD).<ref name="Baradaran"/> While the MCU can intake calcium without the NTD, the NTD has regulatory functions, including bending <scene name='83/837230/Transmembrane_domain/3'>transmembrane helices</scene> to constrict the pore.<ref name="Baradaran"/><ref name="Fan"/> Reorganization in the NTD due to shifts in the The <scene name='83/837230/Coiled_coil/3'>coiled coil</scene> domain alters membrane packing, facilitating a rotamer switch between a pair of tyrosine residues controlling calcium flow through the pore. The soluble domain is wider than the transmembrane domain (Figure 1), allowing calcium ions to rehydrate and increasing the conductivity of ions through the uniporter into the mitochondrial matrix.<ref name="Fan" />
| + | Each leg of the coiled-coil domain extends into the <scene name='83/832952/New_ones/4'>NTD</scene>.<ref name="Baradaran"/> The soluble domain, including the linker, coiled-coil, and NTD, is wider than the transmembrane domain (Figure 1), allowing calcium ions passed through the selectivity filter to rehydrate, increasing the conductivity of ions through the uniporter into the mitochondrial matrix.<ref name="Fan" /> While the MCU can intake calcium without the NTD, the NTD serves regulatory functions, including bending <scene name='83/837230/Transmembrane_domain/3'>transmembrane helices</scene> to constrict the pore.<ref name="Baradaran"/><ref name="Fan"/> Reorganization in the NTD due to shifts in the <scene name='83/837230/Coiled_coil/3'>coiled coil</scene> domain alters membrane packing, facilitating a rotamer switch between a pair of tyrosine residues controlling calcium flow through the pore. |
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| | ===Selectivity Filter=== | | ===Selectivity Filter=== |
| - | [[Image:Electronegativity_MCU_4.jpg|250 px|right|thumb|Figure 3: Electronegativity of the MCU viewed from outside the channel. The high concentration of negative charge (shown in red) attracts the positive calcium ions. [https://en.wikipedia.org/wiki/Protein_Data_Bank PDB] [https://www.rcsb.org/structure/6DT0 6DT0]]] | + | [[Image:Electronegativity_MCU_4.jpg|250 px|right|thumb|Figure 3: Electrostatic potential of MCU viewed from the intermembrane space. The high concentration of negatively charged residues (red), surrounding the selectivity filter, attracts the positively charged calcium ions [https://en.wikipedia.org/wiki/Protein_Data_Bank PDB] [https://www.rcsb.org/structure/6DT0 6DT0]]] |
| - | The <scene name='83/832952/Selectivity_filter/3'>selectivity filter</scene> of the MCU is composed by many acidic amino acids near the narrow mouth of the channel which leads to high affinity for calcium ([https://en.wikipedia.org/wiki/Dissociation_constant dissociation constant] of less than 2nM) (Figure 3).<ref name="Baradaran"/> Negatively charged aspartates <scene name='83/832952/New_ones/2'>(Asp221)</scene> at the mouth of the MCU congregate positively charged <scene name='83/832952/Calcium/4'>calcium ions</scene> at the entrance of the channel.<ref name="Baradaran"/> A highly conserved <scene name='83/832952/Dxxe_motif/7'>WDXXEP</scene> [https://en.wikipedia.org/wiki/Sequence_motif motif] in the TM2 helices form the selectivity pore which selects for calcium transport over other similar ions.<ref name="Baradaran"/> | + | The <scene name='83/832952/Selectivity_filter/3'>selectivity filter</scene> of the MCU is composed of multiple layers of acidic amino acids near the narrow mouth of the channel and is responsible for the high affinity and selectivity of the MCU for calcium ([https://en.wikipedia.org/wiki/Dissociation_constant dissociation constant] of less than 2nM) (Figure 3).<ref name="Baradaran"/> Negatively charged aspartates <scene name='83/832952/New_ones/2'>(Asp333)</scene> at the mouth of the MCU congregate positively charged <scene name='83/832952/Calcium/4'>calcium ions</scene> at the entrance of the channel.<ref name="Baradaran"/> A highly conserved <scene name='83/832952/Dxxe_motif/7'>WDXXEP</scene> [https://en.wikipedia.org/wiki/Sequence_motif motif] in the TM2 helices form the selectivity pore which selects for calcium transport over other similar ions.<ref name="Baradaran"/> |
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| - | The <scene name='83/832952/Dxxe_motif/7'>WDXXEP</scene> motif consists of <scene name='83/832952/Tryptophan/2'>Trp224</scene> at the N-terminal end, <scene name='83/832952/Selectivity_filter_asp/2'>Asp225</scene>, <scene name='83/832952/Selectivity_filter_glu/3'>Glu228</scene>, and <scene name='83/832952/New_ones/5'>Pro229</scene>.<ref name="Baradaran"/> The negatively charged side chains of Asp225 and <scene name='83/832933/Glu_358/4'>Glu228</scene> point towards the pore.<ref name="Baradaran"/> The <scene name='83/832933/Diameter/2'>diameter</scene> of the carboxyl ring is about 4Å, allowing only a dehydrated Ca<sup>2+</sup> ion to bind. The combination of these radii and high negative charge (Figure 3) account for the selectivity of the MCU. For example, potassium has an [https://en.wikipedia.org/wiki/Ionic_radius ionic radius] of 1.38Å which is much larger than the 1.00Å ionic radius of calcium and potassium cannot fit into the negatively charged ring formed by <scene name='83/832952/Selectivity_filter_glu/3'>Glu228</scene>.<ref name="Baradaran"/> Additionally, even though sodium ions have a similar ionic radius, the +2 charge on calcium is better matched to coordination with the glutamate residues.<ref name="Baradaran"/> | + | The <scene name='83/832952/Dxxe_motif/7'>WDXXEP</scene> motif consists of <scene name='83/832952/Tryptophan/2'>Trp332</scene> at the N-terminal end, <scene name='83/832952/Selectivity_filter_asp/2'>Asp333</scene>, <scene name='83/832952/Selectivity_filter_glu/3'>Glu336</scene>, and <scene name='83/832952/New_ones/5'>Pro337</scene>.<ref name="Baradaran"/> The negatively charged side chains of Asp333 and <scene name='83/832933/Glu_358/4'>Glu336</scene> point towards the pore.<ref name="Baradaran"/> The <scene name='83/832933/Diameter/2'>diameter</scene> of the pore created by the carboxyl ring on the 4 identical glutamates (Glu336) is about 4Å, allowing only a dehydrated Ca<sup>2+</sup> ion to bind. The combination of these radii and high negative charge (Figure 3) account for the selectivity of the MCU. For example, potassium has an [https://en.wikipedia.org/wiki/Ionic_radius ionic radius] of 1.38Å which is much larger than the 1.00Å ionic radius of calcium and thus cannot fit through the pore.<ref name="Baradaran"/> Additionally, even though sodium ions have a similar ionic radius, the +2 charge on calcium is better matched for coordination with the glutamate residues.<ref name="Baradaran"/> |
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| - | scene name='83/832952/Tryptophan_proline/2'>Trp224 and Pro229</scene> pack against each other and are oriented towards the pore, but only serve to stabilize <scene name='83/832952/Selectivity_filter_glu/4'>Asp225 and Glu228</scene> and not interact with calcium ions.<ref name="Baradaran"/><ref name="Fan"/> Trp224 stabilizes the carbonyl side chains through <scene name='83/832933/H_bond_trp354_glu358/3'>hydrogen bonding</scene> and anion pi interactions. These Trp residues also form stacking interactions with Pro229, which orientate the Glu carboxyl side chains towards the middle of the pore to interact with Ca<sup>2+</sup> ions.<ref name=”Yoo”>PMID:29954988</ref> Approximately one helical turn below the glutamate ring of the selectivity filter, there is a tyrosine ring coming a 12Å wide pore allowing high conductivity. <ref name="Fan" /> The wider opening allows calcium to rehydrate once they pass the selectivity pore. | + | The additional residues of the WDXXEP motif, <scene name='83/832952/Tryptophan_proline/2'>Trp332 and Pro337</scene> pack against each other, are oriented towards the pore, and serve to stabilize <scene name='83/832952/Selectivity_filter_glu/4'>Asp333 and Glu336</scene>.<ref name="Baradaran"/><ref name="Fan"/> Trp332 stabilizes the carbonyl side chains of Glu336 through <scene name='83/832933/H_bond_trp354_glu358/3'>hydrogen bonding</scene> and anion pi interactions. Approximately one helical turn below the glutamate ring of the selectivity filter, a wider tyrosine ring (12Å) facilitates calcium rehydration after passage through the selectivity pore.<ref name="Fan"/> |
| - | [http://www.rcsb.org/structure/6DT0 Calcium Uniporter Structure] The X residues (<scene name='83/832952/New_ones/6'>Val226 and Met227</scene> in this case) face away from the pore and are exposed to the membrane.<ref name="Baradaran"/>
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| | ===Movement of Calcium=== | | ===Movement of Calcium=== |
| - | Cryo-EM showed three <scene name='83/832952/Starting_scene/5'>calciums</scene> in the MCU channel of roughly spherical density equally spaced 6Å apart.<ref name="Baradaran"/> Sites 1 and 2 lie within the <scene name='83/832952/Selectivity_filter/3'>selectivity filter</scene> and likely contain calcium, but site 3 could be calcium or some other small molecule.<ref name="Baradaran"/> Site 1 is positioned in the ring formed by <scene name='83/832952/Selectivity_filter_asp/2'>Asp225</scene> residues and there is a distance of 4Å between the center of the site and each [https://en.wikipedia.org/wiki/Carboxylate carboxylate group] indicating presence of water.<ref name="Baradaran"/> The second site is positioned in the ring formed by <scene name='83/832952/Selectivity_filter_glu/3'>Glu228</scene> and there is a distance of 2.8Å between the carboxylate group of each residue and the middle of the site indicating absence of water.<ref name="Baradaran"/> For transporting calcium, it is proposed that one calcium ion coordinated with water positioned in site 1 loses its water and moves to site 2 and a calcium ion moves from the intermembrane space into site 1.<ref name="Baradaran"/> Meanwhile, a different calcium ion moves from site 2 to site 3 or the mitochondrial matrix.<ref name="Baradaran"/> | + | Cryo-EM showed three <scene name='83/832952/Starting_scene/5'>calciums</scene> in the MCU channel of roughly spherical density equally spaced 6Å apart.<ref name="Baradaran"/> Sites 1 and 2 lie within the <scene name='83/832952/Selectivity_filter/3'>selectivity filter</scene> and likely contain calcium, but site 3 could be calcium or some other small molecule.<ref name="Baradaran"/> Site 1 is positioned in the ring formed by <scene name='83/832952/Selectivity_filter_asp/2'>Asp333</scene> residues with a distance of 8Å between the center of the site and each [https://en.wikipedia.org/wiki/Carboxylate carboxylate group] indicating the presence of water.<ref name="Baradaran"/> Site 2 is positioned in the ring formed by <scene name='83/832952/Selectivity_filter_glu/3'>Glu336</scene> with a smaller distance (4.0Å) between the carboxylate group of each residue and the middle of the site, indicating the absence of water.<ref name="Baradaran"/> For transporting calcium, a mechanism has been proposed where one calcium ion coordinated with water positioned in site 1 is dehydrated and moves to site 2 while a new calcium ion moves from the intermembrane space into site 1.<ref name="Baradaran"/> Meanwhile, a different calcium ion moves from site 2 to site 3 and becomes rehydrated upon passage into the mitochondrial matrix.<ref name="Baradaran"/> |
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| | ===Mutations=== | | ===Mutations=== |
| - | A number of mutations completely eliminate calcium uptake by the MCU. For example, mutation of Trp224, Asp225, Glu228, or Pro229 of the <scene name='83/832952/Dxxe_motif/7'>WDXXEP motif</scene> altered the highly conserved selectivity filter and completely eliminated calcium uptake.<ref name="Baradaran"/><ref name="Fan"/> Even mutating Glu228 to an aspartate significantly changes the dimensions of the pore and inhibits uptake of calcium. However, mutation of either X residue was not detrimental to calcium uptake.<ref name="Baradaran"/> Furthermore, mutation of the tyrosine residue directly below the selectivity filter substantially impaired calcium intake and proper protein folding.<ref name="Fan"/> The residue on TM1 that affected calcium uptake the most in human MCU was Trp317 (analogous to <scene name='83/832952/New_ones/7'>Trp210</scene> in ''C. europaea'') which has a side chain constituting a primary contact point between TM1 and TM2.<ref name="Fan"/> Mutation of human MCU Phe326 (analogous to <scene name='83/832952/New_ones/8'>Phe218</scene> in ''C. europaea'') or Gly331 of the TM1-TM2 linker (<scene name='83/832952/New_ones/9'>Gly223</scene> in ''C. europaea'') affected the linker conformation and configuration of the pore entrance and impaired calcium intake.<ref name="Fan"/> | + | A number of mutations completely eliminate calcium uptake by the MCU. For example, mutation of an residue in the <scene name='83/832952/Dxxe_motif/7'>WDXXEP motif</scene>, with the exception of the two "X" residues, altered the highly conserved selectivity filter and completely eliminated calcium uptake.<ref name="Baradaran"/><ref name="Fan"/> Even substituting Glu336 with an aspartate residue significantly changes the dimensions of the pore and inhibits uptake of calcium. Mutation of the secondary tyrosine ring substantially impaired calcium intake and proper protein folding.<ref name="Fan"/> Additional mutations outside the selectivity filter also impacted calcium uptake, including Trp317 (analogous to <scene name='83/832952/New_ones/7'>Trp210</scene> in ''C. europaea'') which has a side chain constituting a primary contact point between TM1 and TM2.<ref name="Fan"/> Mutation of human MCU Phe326 (analogous to <scene name='83/832952/New_ones/8'>Phe218</scene> in ''C. europaea'') or Gly331 of the TM1-TM2 linker (<scene name='83/832952/New_ones/9'>Gly223</scene> in ''C. europaea'') also affected the linker conformation and configuration of the pore entrance and impaired calcium intake.<ref name="Fan"/> |
| | | | |
| | ==Regulation and Inhibition== | | ==Regulation and Inhibition== |
| | [[Image:Ruthenium_Inhibitors.jpg|220 px|right|thumb|Figure 4: Structures of the ruthenium-based inhibitors of the MCU. Created using ChemDraw Professional 16.0]] | | [[Image:Ruthenium_Inhibitors.jpg|220 px|right|thumb|Figure 4: Structures of the ruthenium-based inhibitors of the MCU. Created using ChemDraw Professional 16.0]] |
| - | The most well-known and commonly used inhibitor of the MCU is [https://en.wikipedia.org/wiki/Ruthenium_red ruthenium red] (RuRed).<ref name="Woods"/> RuRed is a trinuclear, oxo-bridged complex that effectively inhibits calcium uptake without affecting mitochondrial respiration or calcium efflux. The disadvantage of ruthenium red is its challenging purification.<ref name="Woods"/> Interestingly, a compound identified in an impure version of RuRed, termed [https://en.wikipedia.org/wiki/Ru360 Ru360], was found to be the actual active component as an inhibitor of the MCU (Figure 4). Ru360 is a binuclear, oxo-bridged complex with a similar structure to that of RuRed. The only flaw with Ru360 was that it showed low cell permeability, so Ru265 was subsequently developed with twice the cell permeability of Ru360. Ru265 possesses two bridged Ru centers bridged by a nitride ligand (Figure 4).<ref name="Woods"/> | + | The most well-known and commonly used inhibitor of the MCU is [https://en.wikipedia.org/wiki/Ruthenium_red ruthenium red] (RuRed).<ref name="Woods"/> RuRed is a trinuclear, oxo-bridged complex that effectively inhibits calcium uptake without affecting mitochondrial respiration or calcium efflux. The disadvantage of ruthenium red is its challenging purification.<ref name="Woods"/> Interestingly, a compound identified in an impure version of RuRed, termed [https://en.wikipedia.org/wiki/Ru360 Ru360], was found to be the actual active component as an inhibitor of the MCU (Figure 4). Ru360 is a binuclear, oxo-bridged complex with a similar structure to that of RuRed. To increase the cell permeability of Ru360, the derivative Ru265 was subsequently which had twice the cell permeability of Ru360. Ru265 possesses two bridged Ru centers bridged by a nitride ligand (Figure 4).<ref name="Woods"/> |
| | | | |
| | Recent experiments suggest that Ru360 inhibits calcium uptake through interactions with the <scene name='83/832952/Dxxe_motif/7'>WDXXEP</scene> motif. However, not much is known about the mode of inhibition. Also, mutations of Asp261 and Ser259 in human MCU were shown to maintain calcium uptake into the matrix, but reduce the inhibitory effect of Ru360, but not Ru265. However, a mutation in a cysteine residue in the <scene name='83/832952/New_ones/4'>NTD</scene> had the opposite effect as it reduced the inhibitory effects of Ru265, but not Ru360 (Figure 4).<ref name="Woods"/> | | Recent experiments suggest that Ru360 inhibits calcium uptake through interactions with the <scene name='83/832952/Dxxe_motif/7'>WDXXEP</scene> motif. However, not much is known about the mode of inhibition. Also, mutations of Asp261 and Ser259 in human MCU were shown to maintain calcium uptake into the matrix, but reduce the inhibitory effect of Ru360, but not Ru265. However, a mutation in a cysteine residue in the <scene name='83/832952/New_ones/4'>NTD</scene> had the opposite effect as it reduced the inhibitory effects of Ru265, but not Ru360 (Figure 4).<ref name="Woods"/> |
| | | | |
| | ==Medical Relevance== | | ==Medical Relevance== |
| - | The MCU has a large role in disease because of its effect on apoptosis and cell signaling. The overload of the mitochondrial matrix with calcium leads to release of [https://en.wikipedia.org/wiki/Cytochrome_c cytochrome c], overproduction of [https://en.wikipedia.org/wiki/Reactive_oxygen_species reactive oxygen species], mitochondrial swelling, and the opening of the mitochondrial permeability transition pore ([https://en.wikipedia.org/wiki/Mitochondrial_permeability_transition_pore mPTP]) which all lead to apoptotic cell death.<ref name="Woods"/> This connection between mitochondrial calcium and apoptosis makes MCU dysregulation a large contributor to cell death and disease. Calcium machinery in the mitochondria are targets for [https://en.wikipedia.org/wiki/Oncogene proto-oncogenes] and [https://en.wikipedia.org/wiki/Tumor_suppressor tumor suppressors] for this very reason.<ref name="Giorgi"/> Apoptosis can either be induced or repressed. Furthermore, external stimuli can activate receptors in the endoplasmic reticulum that release calcium and activate signal transductions.<ref name="Wang"/> Sequestration of calcium in the mitochondria is vital to shut down these activations, so any impact in movement of calcium ions can cause a wide variety of diseases.<ref name="Wang"/> | + | The MCU is connected with various diseases due to its effect on apoptosis and cell signaling. The overload of the mitochondrial matrix with calcium leads to release of [https://en.wikipedia.org/wiki/Cytochrome_c cytochrome c], overproduction of [https://en.wikipedia.org/wiki/Reactive_oxygen_species reactive oxygen species], mitochondrial swelling, and the opening of the mitochondrial permeability transition pore ([https://en.wikipedia.org/wiki/Mitochondrial_permeability_transition_pore mPTP]) which all lead to apoptotic cell death.<ref name="Woods"/> This connection between mitochondrial calcium and apoptosis makes MCU dysregulation a large contributor to cell death and disease. Calcium machinery in the mitochondria are targets for [https://en.wikipedia.org/wiki/Oncogene proto-oncogenes] and [https://en.wikipedia.org/wiki/Tumor_suppressor tumor suppressors] for this very reason.<ref name="Giorgi"/> Apoptosis can either be induced or repressed. Furthermore, external stimuli can activate receptors in the endoplasmic reticulum that release calcium and activate signal transductions.<ref name="Wang"/> Sequestration of calcium in the mitochondria is vital to shut down these activations, so any impact in movement of calcium ions can cause a wide variety of diseases.<ref name="Wang"/> |
| | | | |
| | ===Neurodegenerative Disorders=== | | ===Neurodegenerative Disorders=== |
| - | Disruption in calcium homeostasis leads to a wide range of [https://en.wikipedia.org/wiki/Neurodegeneration neurodegenerative disorders]. The MCU complex has been identified to play a large role in [https://en.wikipedia.org/wiki/Neuromuscular_disease neuromuscular disease] because of a loss of function of the MICU1 subunit.<ref name="Woods"/> This causes [https://en.wikipedia.org/wiki/Myopathy myopathy], learning difficulties, and progressive movement disorders which can be lethal. In [https://en.wikipedia.org/wiki/Alzheimer%27s_disease Alzheimer's disease], the buildup of [https://en.wikipedia.org/wiki/Amyloid_beta amyloid-β] plaques in the brain leads to increased calcium uptake in [https://en.wikipedia.org/wiki/Neuron neurons] and cell death. Similarly, in early onset [https://en.wikipedia.org/wiki/Parkinson%27s_disease Parkinson's disease], degradation of MICU1 by the ligase [http://proteopedia.org/wiki/index.php/Parkin Parkin] leads to increased mitochondrial calcium uptake, overload, and death. Finally, disrupted glutamate homeostasis in [https://en.wikipedia.org/wiki/Astrocyte astrocytes] and neurons leads to calcium overload and cell death via [https://en.wikipedia.org/wiki/Excitotoxicity excitotoxicity] in Amyotrophic Lateral Sclerosis ([https://en.wikipedia.org/wiki/Amyotrophic_lateral_sclerosis ALS]).<ref name="Woods"/> | + | Disruption in calcium homeostasis leads to a wide range of [https://en.wikipedia.org/wiki/Neurodegeneration neurodegenerative disorders]. The MCU complex plays a role in [https://en.wikipedia.org/wiki/Neuromuscular_disease neuromuscular disease] because of a loss of function of the MICU1 subunit.<ref name="Woods"/> Mutation of MICU1 causes [https://en.wikipedia.org/wiki/Myopathy myopathy], learning difficulties, and progressive movement disorders which can be lethal. In [https://en.wikipedia.org/wiki/Alzheimer%27s_disease Alzheimer's disease], the buildup of [https://en.wikipedia.org/wiki/Amyloid_beta amyloid-β] plaques in the brain leads to increased calcium uptake in [https://en.wikipedia.org/wiki/Neuron neurons] and cell death. Similarly, in early onset [https://en.wikipedia.org/wiki/Parkinson%27s_disease Parkinson's disease], degradation of MICU1 by the ligase [http://proteopedia.org/wiki/index.php/Parkin Parkin] leads to increased mitochondrial calcium uptake, overload, and death. Finally, disrupted glutamate homeostasis in [https://en.wikipedia.org/wiki/Astrocyte astrocytes] and neurons leads to calcium overload and cell death via [https://en.wikipedia.org/wiki/Excitotoxicity excitotoxicity] in Amyotrophic Lateral Sclerosis ([https://en.wikipedia.org/wiki/Amyotrophic_lateral_sclerosis ALS]).<ref name="Woods"/> |
| | | | |
| | ===Diabetes=== | | ===Diabetes=== |
| - | Calcium homeostasis misregulation has also been proven to be instrumental in [https://en.wikipedia.org/wiki/Obesity obesity], [https://en.wikipedia.org/wiki/Insulin_resistance insulin resistance], and [https://en.wikipedia.org/wiki/Type_2_diabetes type-II diabetes].<ref name="Wang"/> The intracellular calcium concentrations in primary [https://en.wikipedia.org/wiki/Adipocyte adipocytes] from obese human subjects has been found to be elevated. Any inhibition of downstream calcium signaling could decrease movement of the [http://proteopedia.org/wiki/index.php/GLUT4 GLUT4] glucose transporter and glucose uptake. Additionally, removal of MCU in [https://en.wikipedia.org/wiki/Beta_cell β-cells] in the [https://en.wikipedia.org/wiki/Pancreas pancreas] demonstrated a decrease in cellular ATP concentration following glucose stimulation which resulted in decreased glucose-stimulated insulin secretion. | + | Calcium homeostasis misregulation is also instrumental in [https://en.wikipedia.org/wiki/Obesity obesity], [https://en.wikipedia.org/wiki/Insulin_resistance insulin resistance], and [https://en.wikipedia.org/wiki/Type_2_diabetes type-II diabetes].<ref name="Wang"/> The intracellular calcium concentrations in primary [https://en.wikipedia.org/wiki/Adipocyte adipocytes] from obese human subjects are elevated. Any inhibition of downstream calcium signaling could decrease movement of the [http://proteopedia.org/wiki/index.php/GLUT4 GLUT4] glucose transporter and glucose uptake. Additionally, removal of MCU in [https://en.wikipedia.org/wiki/Beta_cell β-cells] in the [https://en.wikipedia.org/wiki/Pancreas pancreas] demonstrated a decrease in cellular ATP concentration following glucose stimulation which resulted in decreased glucose-stimulated insulin secretion. |
| | | | |
| | ===Heart Failure=== | | ===Heart Failure=== |
|
Overview
The mitochondrial calcium uniporter (MCU) complex is the main source of entry for calcium ions into the mitochondrial matrix from the intermembrane space. MCU channels exist in most eukaryotes, but activity is regulated differently in each clade.[1] MCU was definitively assigned in 2011 using a combination of NMR spectroscopy, cryoelectron microscopy, and x-ray crystallography.[2] Recent cryoelectron microscopy (cryo-EM) analysis provides a structural framework for understanding the mechanism for calcium selectivity by the MCU.[3] Like other ion channels, the MCU is highly selective and efficient, allowing calcium ions into the mitochondrial matrix at a rate of 5,000,000 ions per second, even though potassium ions are over 100,000 times more abundant in the intermembrane space.[1]
Under resting conditions, the calcium concentration in the mitochondria is about the same as in the cytoplasm, but when stimulated, mitochondrial calcium concentration increases 10 to 20-fold.[3] Mitochondria-associated ER membranes exist between the mitochondria and the endoplasmic reticulum facilitate efficient transport of calcium ions.[4] The transfer of electrons through respiratory complexes I-IV produces the energy to pump hydrogen ions into the intermembrane space and establish the proton electrochemical gradient potential.[3] This negative electrochemical potential is the driving force that moves positively charged calcium ions into the mitochondrial matrix.[3] Calcium uptake and efflux must be tightly regulated to controll essential Krebs cycle enzyme activity, including pyruvate dehydrogenase, α-ketoglutarate dehydrogenase, and isocitrate dehydrogenase, while avoiding calcium overload and apoptosis.[4]
Mitochondrial Calcium Uniporter Complex
The MCU complex exists as a large complex (around 480 kDa in humans) made up of both pore-forming and regulatory subunits.[4] The MCU complex is composed of the MCU as well as regulatory subunits including the mitochondrial calcium uptake proteins MICU1 and MICU2, essential MICU regulator (EMRE), MCU regulatory subunit b (MCUb), and MCU regulator 1 (MCUR1). [5] The mitochondrial uptake proteins (MICU1 and MICU2) are intermembrane regulatory proteins that use their EF hand domains to grab intermembrane calcium and to control transport through the channel of the MCU.[4] When calcium ion concentration in the intermembrane space is low, MICU1 and 2 block the MCU to prevent uptake of calcium.[4] In high calcium concentrations, calcium binds to these regulatory proteins and they undergo a conformational change to allow calcium ions through the MCU and into the matrix.[4] When calcium levels are below 500 nM, MICU1 can block movement of calcium by itself, calcium levels between 500 nM and 1,500 nM require both MICU1 and MICU2 to block ion entry, and any concentration over 1,500 nM is sufficient for calcium entry.[3] Another regulatory protein, MCUR1 is a cofactor in the assembly of the respiratory chain rather than an essential part of the uniporter.[3] Though the MCU is able to take up calcium independently, two other membrane spanning subunits, the MCUb and the essential MCU regulator (EMRE), connect to the MCI and add further regulatory mechanisms.[4] MCUb is similar to MCU, but through key amino acid substitutions serves an inhibitory role.[4] The EMRE contributes to regulation of calcium intake in the by connecting MICU1 and MICU2 to the MCU.[3][4]
 Figure 1: Structure of mitochondrial calcium uniporter colored by functional domain. The transmembrane domain is highlighted in salmon, the linker domain spanning the mitochondrial matrix in light cyan, coiled-coil domain in dark violet, and the N-terminal domain in slate blue. PDB 6DT0 MCU Structure
The is the ion channel component of the MCU complex (Figure 1). An NMR structure of an inactive MCU from C. elegans showed a pentameric arrangement, but the recent crystal and cryo-EM structures of multiple MCUs reaffirmed that active eukaryotic MCU exists as four monomers, identical in sequence, arranged and packed together such that they structurally form a in a tetrameric truncated pyramid (Figure 2).[2] The MCU protein is composed of a , a , and a (NTD) (Figure 1).[2] The hydrophobic is located in the (inner mitochondrial membrane) while the hydrophilic coiled-coil domain and NTD are positioned in the mitochondrial matrix.[1]
 Figure 2: Symmetry and organization of MCU dimer of dimers viewed from the inner mitochondrial membrane PDB 6DT0 Transmembrane Domain
The is inserted into the inner mitochondrial membrane and opens to the inner membrane space (Figure 1). The consists of eight separate helices (TM1 and TM2 from each subunit) with symmetry that are connected by hydrophobic amino acids in the intermembrane space (Figure 2).[1] The small pore, highly specific for calcium binding is located in the interior of the bundle of four packed helices while the four helices of surround this TM2 bundle. packs tightly against from the neighboring subunit which conveys a sense of domain-swapping.[5]
Coiled-coil Domain
The N-terminal domains of the helices extend into the matrix and form coiled-coils with a C-terminal helix.[1] These "legs" are separated from each other which allows enough space for calcium ions to diffuse out into the matrix.[1] The domain is the first subsection of the soluble domain, which resides in the inner mitochondrial membrane. The coiled coil functions as the joints of the uniporter, providing flexibility to promote transport of Ca2+ions down their concentration gradient.[5] When Ca2+ ions binds to the selectivity pore, the coiled-coil swings approximately 8° around its end near the . This movement propagates to the top of the transmembrane domain, where the pore is located about 85 Å away. The coiled coil's flexibility can be attributed to the disordered packing between subunits. Subunits A and C adopt different conformations than the B and D subunits, although they superimpose closely.[5] The coiled-coil domain is also required for proper assembly of the MCU and is post-translationally modified.[5]
N-terminal Domain
Each leg of the coiled-coil domain extends into the .[1] The soluble domain, including the linker, coiled-coil, and NTD, is wider than the transmembrane domain (Figure 1), allowing calcium ions passed through the selectivity filter to rehydrate, increasing the conductivity of ions through the uniporter into the mitochondrial matrix.[5] While the MCU can intake calcium without the NTD, the NTD serves regulatory functions, including bending to constrict the pore.[1][5] Reorganization in the NTD due to shifts in the domain alters membrane packing, facilitating a rotamer switch between a pair of tyrosine residues controlling calcium flow through the pore.
Selectivity Filter
 Figure 3: Electrostatic potential of MCU viewed from the intermembrane space. The high concentration of negatively charged residues (red), surrounding the selectivity filter, attracts the positively charged calcium ions PDB 6DT0The of the MCU is composed of multiple layers of acidic amino acids near the narrow mouth of the channel and is responsible for the high affinity and selectivity of the MCU for calcium (dissociation constant of less than 2nM) (Figure 3).[1] Negatively charged aspartates at the mouth of the MCU congregate positively charged at the entrance of the channel.[1] A highly conserved motif in the TM2 helices form the selectivity pore which selects for calcium transport over other similar ions.[1]
The motif consists of at the N-terminal end, , , and .[1] The negatively charged side chains of Asp333 and point towards the pore.[1] The of the pore created by the carboxyl ring on the 4 identical glutamates (Glu336) is about 4Å, allowing only a dehydrated Ca2+ ion to bind. The combination of these radii and high negative charge (Figure 3) account for the selectivity of the MCU. For example, potassium has an ionic radius of 1.38Å which is much larger than the 1.00Å ionic radius of calcium and thus cannot fit through the pore.[1] Additionally, even though sodium ions have a similar ionic radius, the +2 charge on calcium is better matched for coordination with the glutamate residues.[1]
The additional residues of the WDXXEP motif, pack against each other, are oriented towards the pore, and serve to stabilize .[1][5] Trp332 stabilizes the carbonyl side chains of Glu336 through and anion pi interactions. Approximately one helical turn below the glutamate ring of the selectivity filter, a wider tyrosine ring (12Å) facilitates calcium rehydration after passage through the selectivity pore.[5]
Movement of Calcium
Cryo-EM showed three in the MCU channel of roughly spherical density equally spaced 6Å apart.[1] Sites 1 and 2 lie within the and likely contain calcium, but site 3 could be calcium or some other small molecule.[1] Site 1 is positioned in the ring formed by residues with a distance of 8Å between the center of the site and each carboxylate group indicating the presence of water.[1] Site 2 is positioned in the ring formed by with a smaller distance (4.0Å) between the carboxylate group of each residue and the middle of the site, indicating the absence of water.[1] For transporting calcium, a mechanism has been proposed where one calcium ion coordinated with water positioned in site 1 is dehydrated and moves to site 2 while a new calcium ion moves from the intermembrane space into site 1.[1] Meanwhile, a different calcium ion moves from site 2 to site 3 and becomes rehydrated upon passage into the mitochondrial matrix.[1]
Mutations
A number of mutations completely eliminate calcium uptake by the MCU. For example, mutation of an residue in the , with the exception of the two "X" residues, altered the highly conserved selectivity filter and completely eliminated calcium uptake.[1][5] Even substituting Glu336 with an aspartate residue significantly changes the dimensions of the pore and inhibits uptake of calcium. Mutation of the secondary tyrosine ring substantially impaired calcium intake and proper protein folding.[5] Additional mutations outside the selectivity filter also impacted calcium uptake, including Trp317 (analogous to in C. europaea) which has a side chain constituting a primary contact point between TM1 and TM2.[5] Mutation of human MCU Phe326 (analogous to in C. europaea) or Gly331 of the TM1-TM2 linker ( in C. europaea) also affected the linker conformation and configuration of the pore entrance and impaired calcium intake.[5]
Regulation and Inhibition
 Figure 4: Structures of the ruthenium-based inhibitors of the MCU. Created using ChemDraw Professional 16.0 The most well-known and commonly used inhibitor of the MCU is ruthenium red (RuRed).[2] RuRed is a trinuclear, oxo-bridged complex that effectively inhibits calcium uptake without affecting mitochondrial respiration or calcium efflux. The disadvantage of ruthenium red is its challenging purification.[2] Interestingly, a compound identified in an impure version of RuRed, termed Ru360, was found to be the actual active component as an inhibitor of the MCU (Figure 4). Ru360 is a binuclear, oxo-bridged complex with a similar structure to that of RuRed. To increase the cell permeability of Ru360, the derivative Ru265 was subsequently which had twice the cell permeability of Ru360. Ru265 possesses two bridged Ru centers bridged by a nitride ligand (Figure 4).[2]
Recent experiments suggest that Ru360 inhibits calcium uptake through interactions with the motif. However, not much is known about the mode of inhibition. Also, mutations of Asp261 and Ser259 in human MCU were shown to maintain calcium uptake into the matrix, but reduce the inhibitory effect of Ru360, but not Ru265. However, a mutation in a cysteine residue in the had the opposite effect as it reduced the inhibitory effects of Ru265, but not Ru360 (Figure 4).[2]
Medical Relevance
The MCU is connected with various diseases due to its effect on apoptosis and cell signaling. The overload of the mitochondrial matrix with calcium leads to release of cytochrome c, overproduction of reactive oxygen species, mitochondrial swelling, and the opening of the mitochondrial permeability transition pore (mPTP) which all lead to apoptotic cell death.[2] This connection between mitochondrial calcium and apoptosis makes MCU dysregulation a large contributor to cell death and disease. Calcium machinery in the mitochondria are targets for proto-oncogenes and tumor suppressors for this very reason.[3] Apoptosis can either be induced or repressed. Furthermore, external stimuli can activate receptors in the endoplasmic reticulum that release calcium and activate signal transductions.[4] Sequestration of calcium in the mitochondria is vital to shut down these activations, so any impact in movement of calcium ions can cause a wide variety of diseases.[4]
Neurodegenerative Disorders
Disruption in calcium homeostasis leads to a wide range of neurodegenerative disorders. The MCU complex plays a role in neuromuscular disease because of a loss of function of the MICU1 subunit.[2] Mutation of MICU1 causes myopathy, learning difficulties, and progressive movement disorders which can be lethal. In Alzheimer's disease, the buildup of amyloid-β plaques in the brain leads to increased calcium uptake in neurons and cell death. Similarly, in early onset Parkinson's disease, degradation of MICU1 by the ligase Parkin leads to increased mitochondrial calcium uptake, overload, and death. Finally, disrupted glutamate homeostasis in astrocytes and neurons leads to calcium overload and cell death via excitotoxicity in Amyotrophic Lateral Sclerosis (ALS).[2]
Diabetes
Calcium homeostasis misregulation is also instrumental in obesity, insulin resistance, and type-II diabetes.[4] The intracellular calcium concentrations in primary adipocytes from obese human subjects are elevated. Any inhibition of downstream calcium signaling could decrease movement of the GLUT4 glucose transporter and glucose uptake. Additionally, removal of MCU in β-cells in the pancreas demonstrated a decrease in cellular ATP concentration following glucose stimulation which resulted in decreased glucose-stimulated insulin secretion.
Heart Failure
Calcium overload in the mitochondria of cardiac cells lead to apoptotic cardiac cell death. Calcium governs excitation contraction coupling of the cardiac muscles, which creates the ATP needed to power the contraction during heart beats. The increase in mitochondrial Ca2+ concentration is essential for the functioning of this muscle contraction. Mitochondrial Ca2+ overload, though, leads to necrotic cardiac cell death and can be targeted with regulation of the MCU. An example of potential treatment might involve the use of Ru360 to inhibit the uptake of Ca2+ ions into the mitochondria.[3]
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