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1. A ferrocene-containing analogue of the MCU inhibitor Ru265 with increased cell permeability

   https://doi.org/10.1039/d2qi02183h  

   Huang, Zhouyang; Spivey, Jesse A.; MacMillan, Samantha N.; Wilson, Justin J. (January 2023, Inorganic Chemistry Frontiers)

   An analogue of the mitochondrial calcium uniporter (MCU) inhibitor Ru265 containing axial ferrocenecarboxylate ligands is reported. This new complex exhibits enhanced cellular uptake compared to the parent compound Ru265. 

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2. Structure‐Activity Relationships of Metal‐Based Inhibitors of the Mitochondrial Calcium Uniporter

   https://doi.org/10.1002/cmdc.202300106  

   Huang, Zhouyang; Wilson, Justin J. (June 2023, ChemMedChem)

   Abstract The mitochondrial calcium uniporter (MCU) is a transmembrane protein that is responsible for mediating mitochondrial calcium (mCa²⁺) uptake. Given this critical function, the MCU has been implicated as an important target for addressing various human diseases. As such, there has a been growing interest in developing small molecules that can inhibit this protein. To date, metal coordination complexes, particularly multinuclear ruthenium complexes, are the most widely investigated MCU inhibitors due to both their potent inhibitory activities as well as their longstanding use for this application. Recent efforts have expanded the metal‐based toolkit for MCU inhibition. This concept paper summarizes the development of new metal‐based inhibitors of the MCU and their structure‐activity relationships in the context of improving their potential for therapeutic use in managing human diseases related tomCa²⁺dysregulation. 

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3. Investigation of Cobalt(III) Cage Complexes as Inhibitors of the Mitochondrial Calcium Uniporter

   https://doi.org/10.1002/ejic.202200735  

   Bigham, Nicholas P.; Wilson, Justin J. (March 2023, European Journal of Inorganic Chemistry)

   Abstract The mitochondrial calcium uniporter (MCU) mediates uptake of calcium ions (Ca²⁺) into the mitochondria, a process that is vital for maintaining normal cellular function. Inhibitors of the MCU, the most promising of which are dinuclear ruthenium coordination compounds, have found use as both therapeutic agents and tools for studying the importance of this ion channel. In this study, six Co³⁺cage compounds with sarcophagine‐like ligands were assessed for their abilities to inhibit MCU‐mediated mitochondrial Ca²⁺uptake. These complexes were synthesized and characterized according to literature procedures and then investigated in cellular systems for their MCU‐inhibitory activities. Among these six compounds, [Co(sen)]³⁺(3, sen=5‐(4‐amino‐2‐azabutyl)‐5‐methyl‐3,7‐diaza‐1,9‐nonanediamine) was identified to be a potent MCU inhibitor, with IC₅₀values of inhibition of 160 and 180 nM in permeabilized HeLa and HEK293T cells, respectively. Furthermore, the cellular uptake of compound3was determined, revealing moderate accumulation in cells. Most notably,3was demonstrated to operate in intact cells as an MCU inhibitor. Collectively, this work presents the viability of using cobalt coordination complexes as MCU inhibitors, providing a new direction for researchers to investigate. 

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4. Modeling the Effects of Calcium Overload on Mitochondrial Ultrastructural Remodeling

   https://doi.org/10.3390/app11052071  

   Strubbe-Rivera, Jasiel O.; Chen, Jiahui; West, Benjamin A.; Parent, Kristin N.; Wei, Guo-Wei; Bazil, Jason N. (March 2021, Applied Sciences)

   null (Ed.)

   Mitochondrial cristae are dynamic invaginations of the inner membrane and play a key role in its metabolic capacity to produce ATP. Structural alterations caused by either genetic abnormalities or detrimental environmental factors impede mitochondrial metabolic fluxes and lead to a decrease in their ability to meet metabolic energy requirements. While some of the key proteins associated with mitochondrial cristae are known, very little is known about how the inner membrane dynamics are involved in energy metabolism. In this study, we present a computational strategy to understand how cristae are formed using a phase-based separation approach of both the inner membrane space and matrix space, which are explicitly modeled using the Cahn–Hilliard equation. We show that cristae are formed as a consequence of minimizing an energy function associated with phase interactions which are subject to geometric boundary constraints. We then extended the model to explore how the presence of calcium phosphate granules, entities that form in calcium overload conditions, exert a devastating inner membrane remodeling response that reduces the capacity for mitochondria to produce ATP. This modeling approach can be extended to include arbitrary geometrical constraints, the spatial heterogeneity of enzymes, and electrostatic effects to mechanize the impact of ultrastructural changes on energy metabolism. 

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5. Ablation of Sam50 is associated with fragmentation and alterations in metabolism in murine and human myotubes

   https://doi.org/10.1002/jcp.31293  

   Shao, Bryanna; Killion, Mason; Oliver, Ashton; Vang, Chia; Zeleke, Faben; Neikirk, Kit; Vue, Zer; Garza‐Lopez, Edgar; Shao, Jian‐qiang; Mungai, Margaret; et al (May 2024, Journal of Cellular Physiology)

   Abstract The sorting and assembly machinery (SAM) Complex is responsible for assembling β‐barrel proteins in the mitochondrial membrane. Comprising three subunits, Sam35, Sam37, and Sam50, the SAM complex connects the inner and outer mitochondrial membranes by interacting with the mitochondrial contact site and cristae organizing system complex. Sam50, in particular, stabilizes the mitochondrial intermembrane space bridging (MIB) complex, which is crucial for protein transport, respiratory chain complex assembly, and regulation of cristae integrity. While the role of Sam50 in mitochondrial structure and metabolism in skeletal muscle remains unclear, this study aims to investigate its impact. Serial block‐face‐scanning electron microscopy and computer‐assisted 3D renderings were employed to compare mitochondrial structure and networking inSam50‐deficient myotubes from mice and humans with wild‐type (WT) myotubes. Furthermore, autophagosome 3D structure was assessed in human myotubes. Mitochondrial metabolic phenotypes were assessed using Gas Chromatography‐Mass Spectrometry‐based metabolomics to explore differential changes in WT andSam50‐deficient myotubes. The results revealed increased mitochondrial fragmentation and autophagosome formation inSam50‐deficient myotubes compared to controls. Metabolomic analysis indicated elevated metabolism of propanoate and several amino acids, including ß‐Alanine, phenylalanine, and tyrosine, along with increased amino acid and fatty acid metabolism inSam50‐deficient myotubes. Furthermore, impairment of oxidative capacity was observed uponSam50ablation in both murine and human myotubes, as measured with the XF24 Seahorse Analyzer. Collectively, these findings support the critical role of Sam50 in establishing and maintaining mitochondrial integrity, cristae structure, and mitochondrial metabolism. By elucidating the impact ofSam50‐deficiency, this study enhances our understanding of mitochondrial function in skeletal muscle. 

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