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Mitochondrial Calcium Uniporter

1 Introduction
2 Structural highlights and mechanism
3 Disease Links
- 3.1 Types 1 and 2 Diabetes
- 3.2 Heart Failure
4 Student Contributors

Introduction

Calcium is a key signaling molecule involved in many physiological functions including muscle contraction, neuron excitability, cell migration and growth. ^[1] The mitochondria are important regulators of calcium in the body; they orchestrate the regulation of ATP production, cell death, and intracellular calcium signaling. ^[2] The process of calcium regulation in the mitochondria is as follows: Calcium moves in one direction through the mitochondria from the intermembrane space through the inner mitochondrial membrane into the matrix. The matrix is more negatively charged driven by the electron transport chain which facilitates calcium movement with its concentration gradient. Maintaining this concentration gradient and the homeostasis of calcium in the mitochondria is the calcium uniporter (MCU). 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). ^[2] On the outside of the uniporter portion of the MCU are mitochondrial calcium uptake 1 and 2 (MICU1 and MICU2). MICU1 and MICU2 act as gatekeepers by setting the calcium uptake threshold for activation of MCU, only allowing calcium uptake at high calcium concentrations. MICU1 and MICU2 bind together and associate with another external subunit, EMRE, to regulate calcium acquisition by the MCU. EMRE connects the MICU1 and MICU2 sensors to MCU therefore regulating calcium uptake for the protein. ^[2] Cryogenic electron microscopy (Cryo-EM) was instrumental in outlining the complete structure of this protein. This analysis led to the discovery of key residues within the structure of the MCU as well as providing a structural framework for understanding the mechanism by with the MCU functions. ^[1]

Structural highlights and mechanism

The MCU is a , described as . The uniporter has only a single strong binding site located in the selectivity pore with specificity for Calcium, near the surface of the inner mitochondrial membrane. ^[2] The Calcium from the cytoplasm enters the mitochondrial inner membrane space through the mitochondrial membrane and is passed to the mitochondrial matrix via the MCU (Figure 1). The transmembrane domain opens to the surface of the inner mitochondrial membrane, while the soluble domain, the coiled coil and the N-terminal domain reside inside the inner mitochondrial membrane, opening to the mitochondrial matrix.

Figure 1: Structure of mitochondrial calcium uniporter colored by functional domain designed in PyMol. The transmembrane domain is highlighted salmon, the matrix in light cyan, coiled coil in dark violet, and the N-Terminal Domain in slate blue. [1] 6DT0 Each domain has a different functional role

Transmembrane Domain

The is on the inner mitochondrial membrane open to the inner membrane space. The small pore, highly specific for calcium binding is located in (TM2) while (TM1) surrounds the pore. The transmembrane domain exhibits four fold rotational symmetry.

Selectivity Filter

The contains , , and to allow calcium to pass through the uniporter. The carboxylate oxygen of the side chains draw in the positive calcium ion. The of the carboxyl ring is about 4Å, allowing only a dehydrated Ca2+ ion to bind. Trp38, which is directly next to the Glu residues, stabilizes the carbonyl side chains through and anion pi interactions. These Trp residues also form stacking interactions with Pro359, which orientate the Glu carboxyl side chains towards the middle of the pore to interact with Ca2+ ions. ^[3] 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. ^[2] The wider opening allows calcium to rehydrate once they pass the selectivity pore. Calcium Uniporter Structure

Soluble Domain

The 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 Calcium ions down their concentration gradient.^[2] 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 well.^[2]

Figure 2: Symmetry and organization of subunits from looking down into the uniporter from the inner mitochondrial membrane[2] 6DT0

When calcium 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 amperes 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 N-Terminal domain (NTD) is involved in calcium condition. Reorganization in the NTD due to shifts in the coiled coil switch subunits to alter membrane packing causing the interactions between the tyrosines and transmembrane helices. This propagation facilitates a rotamer switch between one pair of tyrosine controlling calcium flow through the pore. The soluble domain is wider than the transmembrane domain, allowing calcium ions to rehydrate and increasing the conductivity of ions through the uniporter into the mitochondrial matrix.^[2]

Disease Links

Types 1 and 2 Diabetes

Pancreatic beta cells circulate insulin through the body. Glucose initiates signals allowing these cells to break down sugar and release insulin, which is all stimulated by mitochondrial energy metabolism. Calcium homeostasis plays a fundamental role in ATP production supplying energy to this process. Defects in homeostasis of calcium like chronic calcium depletion, caused by leaky Ryanodine receptors, causes types 1 and 2 diabetes through failure of this mechanism. Treatment involves targeting the MCU and MICU1 to open the calcium channel and allow more uptake of calcium ions into the mitochondria. ^[1]

Heart Failure

Calcium overload in the mitochondria of cardiac cells lead to apoptotic cardiac cell death. Calcium governs excitation contraction coupling (EC 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 treatment would be with the use of Ru360 to inhibit the uptake of Ca2+ ions into the mitochondria. ^[1]

Student Contributors

Holly Rowe
Lizzy Ratz
Madi Summers

References

↑ Cite error: Invalid <ref> tag; no text was provided for refs named Giorgi_C
↑ ^2.0 ^2.1 ^2.2 ^2.3 ^2.4 ^2.5 ^2.6 ^2.7 Fan C, Fan M, Orlando BJ, Fastman NM, Zhang J, Xu Y, Chambers MG, Xu X, Perry K, Liao M, Feng L. X-ray and cryo-EM structures of the mitochondrial calcium uniporter. Nature. 2018 Jul 11. pii: 10.1038/s41586-018-0330-9. doi:, 10.1038/s41586-018-0330-9. PMID:29995856 doi:http://dx.doi.org/10.1038/s41586-018-0330-9
↑ Yoo J, Wu M, Yin Y, Herzik MA Jr, Lander GC, Lee SY. Cryo-EM structure of a mitochondrial calcium uniporter. Science. 2018 Jun 28. pii: science.aar4056. doi: 10.1126/science.aar4056. PMID:29954988 doi:http://dx.doi.org/10.1126/science.aar4056

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_1607"

@@ Line 2: / Line 2: @@
 <StructureSection load='6DT0' size='350' frame='true' side='right' caption='Calcium Uniporter 6DT0' scene=’’>
 ==Introduction==
+[https://en.wikipedia.org/wiki/Calcium_signaling Calcium] is a key signaling molecule involved in many physiological functions including muscle contraction, neuron excitability, cell migration and growth. <ref name="Giorgi C" /> The [https://en.wikipedia.org/wiki/Mitochondrion mitochondria] are important regulators of calcium in the body; they orchestrate the regulation of ATP production, cell death, and intracellular calcium signaling. <ref name="Fan C" /> The process of calcium regulation in the mitochondria is as follows: Calcium moves in one direction through the mitochondria from the [https://en.wikipedia.org/wiki/Intermembrane_space intermembrane space] through the [https://en.wikipedia.org/wiki/Inner_mitochondrial_membrane inner mitochondrial membrane] into the [https://en.wikipedia.org/wiki/Mitochondrial_matrix matrix]. The matrix is more negatively charged driven by the [https://en.wikipedia.org/wiki/Electron_transport_chain electron transport chain] which facilitates calcium movement with its concentration gradient. Maintaining this concentration gradient and the [https://en.wikipedia.org/wiki/Homeostasis homeostasis] of calcium in the mitochondria is the calcium uniporter (MCU). 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 C" /> On the outside of the uniporter portion of the MCU are mitochondrial calcium uptake 1 and 2 (MICU1 and MICU2). MICU1 and MICU2 act as gatekeepers by setting the calcium uptake threshold for activation of MCU, only allowing calcium uptake at high calcium concentrations. MICU1 and MICU2 bind together and associate with another external subunit, EMRE, to regulate calcium acquisition by the MCU. EMRE connects the MICU1 and MICU2 sensors to MCU therefore regulating calcium uptake for the protein. <ref name="Fan C" />
-Calcium is a very important signaling molecule in the body with many physiological functions including muscle contraction, neuron excitability, cell migration and growth. The mitochondria are important regulators of calcium in the body and the calcium uniporter (MCU) maintains calcium homeostasis within the mitochondria. Calcium moves in one direction from the intermembrane space through the inner mitochondrial membrane into the matrix. The matrix is more negative driven by the respiratory chain which draws calcium in and allows calcium to move down its gradient.
+[https://en.wikipedia.org/wiki/Cryogenic_electron_microscopy Cryogenic electron microscopy] (Cryo-EM) was instrumental in outlining the complete structure of this protein. This analysis led to the discovery of key residues within the structure of the MCU as well as providing a structural framework for understanding the mechanism by with the MCU functions. <ref name="Giorgi C" />
-The MCU is a complex. Its MICU1 and MICU2 bind together and associate with EMRE which regulates MCU. The MICU1 and MICU2 act as gatekeepers. EMRE connects the MICU1 and MICU2 sensors to MCU therefore regulating calcium uptake for the protein
-The selectivity pore is an integral part of the protein. This pore contains a group of glutamate with oxygen facing inward forming a carboxylate ring through which calcium enters. This negative carboxylate ring does a good job of pulling the positive calcium into the selectivity pore at the top of the protein.
-[https://en.wikipedia.org/wiki/Cryogenic_electron_microscopy Cryogenic electron microscopy] (Cryo-EM) was instrumental in outlining the complete structure of this protein. <ref name="Giorgi C">DOI 10.1038/s41580-018-0052-8</ref>
 == Structural highlights and mechanism ==
@@ Line 20: / Line 16: @@
 ===Soluble Domain===
-The <scene name='83/837230/Coiled_coil/3'>coiled coil</scene> 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 Calcium ions down their concentration gradient.<ref name="Fan C" /> 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 well.<ref name="Fan C" />  [[Image:Nterm.png|200 px|left|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] [https://www.rcsb.org/structure/6DT0 6DT0]]]When calcium binds to the selectivity pore, the coiled coil swings approximately 8° around its end near the <scene name='83/837230/Nterm/2'>N-Terminal Domain</scene>. This movement propagates to the top of the transmembrane domain, where the pore is located, about 85 amperes 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 N-Terminal domain (NTD)  is involved in calcium condition. Reorganization in the NTD due to shifts in the coiled coil switch subunits to alter membrane packing causing the interactions between the tyrosines and transmembrane helices. This propagation facilitates a rotamer switch between one pair of tyrosine controlling calcium flow through the pore. The soluble domain is wider than the transmembrane domain, allowing calcium ions to rehydrate and increasing the conductivity of ions through the uniporter into the mitochondrial matrix.<ref name="Fan C" />
+The <scene name='83/837230/Coiled_coil/3'>coiled coil</scene> 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 Calcium ions down their concentration gradient.<ref name="Fan C" /> 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 well.<ref name="Fan C" />  [[Image:Nterm.png|200 px|left|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] [https://www.rcsb.org/structure/6DT0 6DT0]]]When calcium binds to the selectivity pore, the coiled coil swings approximately 8° around its end near the <scene name='83/837230/Nterm/2'>N-Terminal Domain</scene>. This movement propagates to the top of the transmembrane domain, where the pore is located, about 85 amperes 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 N-Terminal domain (NTD)  is involved in calcium condition. Reorganization in the NTD due to shifts in the coiled coil switch subunits to alter membrane packing causing the interactions between the tyrosines and transmembrane helices. This propagation facilitates a rotamer switch between one pair of tyrosine controlling calcium flow through the pore. The soluble domain is wider than the transmembrane domain, allowing calcium ions to rehydrate and increasing the conductivity of ions through the uniporter into the mitochondrial matrix.<ref name="Fan C" />
 == Disease Links==
@@ Line 30: / Line 26: @@
 ===Heart Failure===
-Calcium overload in the mitochondria of cardiac cells lead to [https://en.wikipedia.org/wiki/Apoptosis apoptotic] cardiac cell death. Calcium governs [https://en.wikipedia.org/wiki/Cardiac_excitation-contraction_coupling excitation contraction coupling] (EC 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 treatment would be with the use of Ru360 (Figure 3) to inhibit the uptake of Ca2+ ions into the mitochondria. <ref name="Giorgi C" />
+Calcium overload in the mitochondria of cardiac cells lead to [https://en.wikipedia.org/wiki/Apoptosis apoptotic] cardiac cell death. Calcium governs [https://en.wikipedia.org/wiki/Cardiac_excitation-contraction_coupling excitation contraction coupling] (EC 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 treatment would be with the use of Ru360 to inhibit the uptake of Ca2+ ions into the mitochondria. <ref name="Giorgi C" />
 == Student Contributors ==