Your search keyword '"Caldwell, Stuart T."' showing total 29 results

1. Ester Prodrugs of Malonate with Enhanced Intracellular Delivery Protect Against Cardiac Ischemia-Reperfusion Injury In Vivo

Author

Prag, Hiran A., Pala, Laura, Kula-Alwar, Duvaraka, Mulvey, John F., Luping, Du, Beach, Timothy E., Booty, Lee M., Hall, Andrew R., Logan, Angela, Sauchanka, Volha, Caldwell, Stuart T., Robb, Ellen L., James, Andrew M., Xu, Zhelong, Saeb-Parsy, Kourosh, Hartley, Richard C., Murphy, Michael P., and Krieg, Thomas

Published

2022

2. Confirmation of the Cardioprotective Effect of MitoGamide in the Diabetic Heart

Author

Park, Min, Nishimura, Takanori, Baeza-Garza, Carlos D., Caldwell, Stuart T., Pun, Pamela Boon Li, Prag, Hiran A., Young, Tim, Sauchanka, Olga, Logan, Angela, Forkink, Marleen, Gruszczyk, Anja V., Prime, Tracy A., Arndt, Sabine, Naudi, Alba, Pamplona, Reinald, Coughlan, Melinda T., Tate, Mitchel, Ritchie, Rebecca H., Caicci, Federico, Kaludercic, Nina, Di Lisa, Fabio, Smith, Robin A. J., Hartley, Richard C., Murphy, Michael P., and Krieg, Thomas

Published

2020

3. Selective Disruption of Mitochondrial Thiol Redox State in Cells and In Vivo

Author

Booty, Lee M., Gawel, Justyna M., Cvetko, Filip, Caldwell, Stuart T., Hall, Andrew R., Mulvey, John F., James, Andrew M., Hinchy, Elizabeth C., Prime, Tracy A., Arndt, Sabine, Beninca, Cristiane, Bright, Thomas P., Clatworthy, Menna R., Ferdinand, John R., Prag, Hiran A., Logan, Angela, Prudent, Julien, Krieg, Thomas, Hartley, Richard C., and Murphy, Michael P.

Published

2019

4. Succinate accumulation drives ischaemia-reperfusion injury during organ transplantation

Author

Martin, Jack L., Costa, Ana S. H., Gruszczyk, Anja V., Beach, Timothy E., Allen, Fay M., Prag, Hiran A., Hinchy, Elizabeth C., Mahbubani, Krishnaa, Hamed, Mazin, Tronci, Laura, Nikitopoulou, Efterpi, James, Andrew M., Krieg, Thomas, Robinson, Alan J., Huang, Margaret M., Caldwell, Stuart T., Logan, Angela, Pala, Laura, Hartley, Richard C., Frezza, Christian, Saeb-Parsy, Kourosh, and Murphy, Michael P.

Published

2019

5. MitoNeoD: A Mitochondria-Targeted Superoxide Probe

Author

Shchepinova, Maria M., Cairns, Andrew G., Prime, Tracy A., Logan, Angela, James, Andrew M., Hall, Andrew R., Vidoni, Sara, Arndt, Sabine, Caldwell, Stuart T., Prag, Hiran A., Pell, Victoria R., Krieg, Thomas, Mulvey, John F., Yadav, Pooja, Cobley, James N., Bright, Thomas P., Senn, Hans M., Anderson, Robert F., Murphy, Michael P., and Hartley, Richard C.

Published

2017

6. Synthesis of an azido-tagged low affinity ratiometric calcium sensor

Author

Caldwell, Stuart T., Cairns, Andrew G., Olson, Marnie, Chalmers, Susan, Sandison, Mairi, Mullen, William, McCarron, John G., and Hartley, Richard C.

Published

2015

7. Rapid and selective generation of H2S within mitochondria protects against cardiac ischemia-reperfusion injury

Author

Miljkovic, Jan Lj., primary, Burger, Nils, additional, Gawel, Justyna M., additional, Mulvey, John F., additional, Norman, Abigail A.I., additional, Nishimura, Takanori, additional, Tsujihata, Yoshiyuki, additional, Logan, Angela, additional, Sauchanka, Olga, additional, Caldwell, Stuart T., additional, Morris, Jordan L., additional, Prime, Tracy A., additional, Warrington, Stefan, additional, Prudent, Julien, additional, Bates, Georgina R., additional, Aksentijević, Dunja, additional, Prag, Hiran A., additional, James, Andrew M., additional, Krieg, Thomas, additional, Hartley, Richard C., additional, and Murphy, Michael P., additional

Published

2022

8. Incorporating a Polyethyleneglycol Linker to Enhance the Hydrophilicity of Mitochondria‐Targeted Triphenylphosphonium Constructs.

Author

Uno, Shinpei, Harkiss, Alexander H., Chowdhury, Roy, Caldwell, Stuart T., Prime, Tracy A., James, Andrew M., Gallagher, Brendan, Prudent, Julien, Hartley, Richard C., and Murphy, Michael P.

Published

2023

9. Itaconate is an anti-inflammatory metabolite that activates Nrf2 via alkylation of KEAP1

Author

Mills, Evanna L., Ryan, Dylan G., Prag, Hiran A., Dikovskaya, Dina, Menon, Deepthi, Zaslona, Zbigniew, Jedrychowski, Mark P., Costa, Ana S. H., Higgins, Maureen, Hams, Emily, Szpyt, John, Runtsch, Marah C., King, Martin S., McGouran, Joanna F., Fischer, Roman, Kessler, Benedikt M., McGettrick, Anne F., Hughes, Mark M., Carroll, Richard G., Booty, Lee M., Knatko, Elena V., Meakin, Paul J., Ashford, Michael L. J., Modis, Louise K., Brunori, Gino, Svin, Daniel C., Fallon, Padraic G., Caldwell, Stuart T., Kunji, Edmund R. S., Chouchani, Edward T., Frezza, Christian, Dinkova-Kostova, Albena T., Hartley, Richard C., Murphy, Michael P., and ONeill, Luke A.

Subjects

Metabolites -- Research, Physiological research, Activation analysis, Leucine zipper -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Author(s): Evanna L. Mills [1, 2, 3, 4]; Dylan G. Ryan [1]; Hiran A. Prag [5]; Dina Dikovskaya [6]; Deepthi Menon [1]; Zbigniew Zaslona [1]; Mark P. Jedrychowski [2, 3]; [...]

Published

2018

10. Targeting Methylglyoxal in Diabetic Kidney Disease Using the Mitochondria-Targeted Compound MitoGamide

Author

Tan, Sih Min, primary, Lindblom, Runa S. J., additional, Ziemann, Mark, additional, Laskowski, Adrienne, additional, Granata, Cesare, additional, Snelson, Matthew, additional, Thallas-Bonke, Vicki, additional, El-Osta, Assam, additional, Baeza-Garza, Carlos D., additional, Caldwell, Stuart T., additional, Hartley, Richard C., additional, Krieg, Thomas, additional, Cooper, Mark E., additional, Murphy, Michael P., additional, and Coughlan, Melinda T., additional

Published

2021

11. Enhancing the Mitochondrial Uptake of Phosphonium Cations by Carboxylic Acid Incorporation

Author

Pala, Laura, Senn, Hans M., Caldwell, Stuart T., Prime, Tracey A., Warrington, Stefan, Bright, Thomas P., Prag, Hiran A., Wilson, Claire, Murphy, Michael, Hartley, Richard C., Prag, Hiran [0000-0002-4753-8567], Murphy, Mike [0000-0003-1115-9618], and Apollo - University of Cambridge Repository

Subjects

mitochondria, Chemistry, membrane permeation, mitochondria-targeting, phosphonium, membrane potential, computational chemistry, pH gradient

Abstract

There is considerable interest in developing drugs and probes targeted to mitochondria in order to understand and treat the many pathologies associated with mitochondrial dysfunction. The large membrane potential, negative inside, across the mitochondrial inner membrane enables delivery of molecules conjugated to lipophilic phosphonium cations to the organelle. Due to their combination of charge and hydrophobicity, quaternary triarylphosphonium cations rapidly cross biological membranes without the requirement for a carrier. Their extent of uptake is determined by the magnitude of the mitochondrial membrane potential, as described by the Nernst equation. To further enhance this uptake here we explored whether incorporation of a carboxylic acid into a quaternary triarylphosphonium cation would enhance its mitochondrial uptake in response to both the membrane potential and the mitochondrial pH gradient (alkaline inside). Accumulation of aryl propionic acid derivatives depended on both the membrane potential and the pH gradient. However, acetic or benzoic derivatives did not accumulate, due to their lowered pKa. Surprisingly, despite not being taken up by mitochondria, the phenylacetic or phenylbenzoic derivatives were not retained within mitochondria when generated within the mitochondrial matrix by hydrolysis of their cognate esters. Computational studies, supported by crystallography, showed that these molecules passed through the hydrophobic core of mitochondrial inner membrane as a neutral dimer. This finding extends our understanding of the mechanisms of membrane permeation of lipophilic cations and suggests future strategies to enhance drug and probe delivery to mitochondria.

Published

2020

12. Photoactivated release of membrane impermeant sulfonates inside cells

Author

Caldwell, Stuart T., primary, O'Byrne, Sean N., additional, Wilson, Calum, additional, Cvetko, Filip, additional, Murphy, Michael P., additional, McCarron, John G., additional, and Hartley, Richard C., additional

Published

2021

13. Nrf2 is activated by disruption of mitochondrial thiol homeostasis but not by enhanced mitochondrial superoxide production

Author

Cvetko, Filip, primary, Caldwell, Stuart T., additional, Higgins, Maureen, additional, Suzuki, Takafumi, additional, Yamamoto, Masayuki, additional, Prag, Hiran A., additional, Hartley, Richard C., additional, Dinkova-Kostova, Albena T., additional, and Murphy, Michael P., additional

Published

2021

14. Tetra-arylborate lipophilic anions as targeting groups

Author

Gaddale Devanna, Kishore K., primary, Gawel, Justyna M., additional, Prime, Tracy A., additional, Cvetko, Filip, additional, Benincá, Cristiane, additional, Caldwell, Stuart T., additional, Negoda, Alexander, additional, Harrison, Andrew, additional, James, Andrew M., additional, Pavlov, Evgeny V., additional, Murphy, Michael P., additional, and Hartley, Richard C., additional

Published

2021

15. Selective Delivery of Dicarboxylates to Mitochondria by Conjugation to a Lipophilic Cation via a Cleavable Linker

Author

Prag, Hiran A., primary, Kula-Alwar, Duvaraka, additional, Pala, Laura, additional, Caldwell, Stuart T., additional, Beach, Timothy E., additional, James, Andrew M., additional, Saeb-Parsy, Kourosh, additional, Krieg, Thomas, additional, Hartley, Richard C., additional, and Murphy, Michael P., additional

Published

2020

16. Ester Prodrugs of Malonate with Enhanced Intracellular Delivery Protect Against Cardiac Ischemia-Reperfusion Injury In Vivo

Author

Prag, Hiran A., primary, Pala, Laura, additional, Kula-Alwar, Duvaraka, additional, Mulvey, John F., additional, Luping, Du, additional, Beach, Timothy E., additional, Booty, Lee M., additional, Hall, Andrew R., additional, Logan, Angela, additional, Sauchanka, Volha, additional, Caldwell, Stuart T., additional, Robb, Ellen L., additional, James, Andrew M., additional, Xu, Zhelong, additional, Saeb-Parsy, Kourosh, additional, Hartley, Richard C., additional, Murphy, Michael P., additional, and Krieg, Thomas, additional

Published

2020

17. Correction to: The Mitochondria-Targeted Methylglyoxal Sequestering Compound, MitoGamide, Is Cardioprotective in the Diabetic Heart

Author

Tate, Mitchel, primary, Higgins, Gavin C., additional, De Blasio, Miles J., additional, Lindblom, Runa, additional, Prakoso, Darnel, additional, Deo, Minh, additional, Kiriazis, Helen, additional, Park, Min, additional, Baeza-Garza, Carlos D., additional, Caldwell, Stuart T., additional, Hartley, Richard C., additional, Krieg, Thomas, additional, Murphy, Michael P., additional, Coughlan, Melinda T., additional, and Ritchie, Rebecca H., additional

Published

2020

18. A sensitive mass spectrometric assay for mitochondrial CoQ pool redox state in vivo

Author

Burger, Nils, primary, Logan, Angela, additional, Prime, Tracy A., additional, Mottahedin, Amin, additional, Caldwell, Stuart T., additional, Krieg, Thomas, additional, Hartley, Richard C., additional, James, Andrew M., additional, and Murphy, Michael P., additional

Published

2020

19. Selective disruption of mitochondrial thiol redox state in cells and in vivo

Author

Booty, Lee M, Gawel, Justyna M, Cvetko, Filip, Caldwell, Stuart T, Hall, Andrew R, Mulvey, John F, James, Andrew M, Hinchy, Elizabeth C, Prime, Tracy A, Arndt, Sabine, Beninca, Cristiane, Bright, Thomas P, Clatworthy, Menna R, Ferdinand, John R, Prag, Hiran A, Logan, Angela, Prudent, Julien, Krieg, Thomas, Hartley, Richard C, and Murphy, Michael P

Subjects

mitochondria, mitochondria targeting, thioredoxin, glutathione, thiol redox state, redox signaling

Abstract

Mitochondrial glutathione (GSH) and thioredoxin (Trx) systems function independently of the rest of the cell. While maintenance of mitochondrial thiol redox state is thought vital for cell survival, this was not testable due to the difficulty of manipulating the organelle's thiol systems independently of those in other cell compartments. To overcome this constraint we modified the glutathione S-transferase substrate and Trx reductase (TrxR) inhibitor, 1-chloro-2,4-dinitrobenzene (CDNB) by conjugation to the mitochondria-targeting triphenylphosphonium cation. The result, MitoCDNB, is taken up by mitochondria where it selectively depletes the mitochondrial GSH pool, catalyzed by glutathione S-transferases, and directly inhibits mitochondrial TrxR2 and peroxiredoxin 3, a peroxidase. Importantly, MitoCDNB inactivates mitochondrial thiol redox homeostasis in isolated cells and in vivo, without affecting that of the cytosol. Consequently, MitoCDNB enables assessment of the biomedical importance of mitochondrial thiol homeostasis in reactive oxygen species production, organelle dynamics, redox signaling, and cell death in cells and in vivo.

Published

2019

20. Mitochondrial oxidative stress causes insulin resistance without disrupting oxidative phosphorylation

Author

Fazakerley, Daniel J., Minard, Annabel Y., Krycer, James R., Thomas, Kristen C., Stöckli, Jacqueline, Harney, Dylan J., Burchfield, James G., Maghzal, Ghassan J., Caldwell, Stuart T., Hartley, Richard C., Stocker, Roland, Murphy, Michael P., James, David E., Fazakerley, Daniel [0000-0001-8241-2903], Murphy, Mike [0000-0003-1115-9618], and Apollo - University of Cambridge Repository

Subjects

Male, Paraquat, insulin, muscle, hydrogen peroxide, adipocyte, Oxidative Phosphorylation, Electron Transport, Myoblasts, Mice, Oxygen Consumption, Superoxides, insulin resistance, 3T3-L1 Cells, Adipocytes, oxidative stress, Animals, Protein Isoforms, superoxide ion, Glucose Transporter Type 4, Herbicides, Adenylate Kinase, Peroxiredoxins, adipose tissue, Mitochondria, Mice, Inbred C57BL, Glucose, Mitochondrial dysfunction

Abstract

Mitochondrial oxidative stress, mitochondrial dysfunction, or both have been implicated in insulin resistance. However, disentangling the individual roles of these processes in insulin resistance has been difficult because they often occur in tandem, and tools that selectively increase oxidant production without impairing mitochondrial respiration have been lacking. Using the dimer/monomer status of peroxiredoxin isoforms as an indicator of compartmental hydrogen peroxide burden, we provide evidence that oxidative stress is localized to mitochondria in insulin-resistant 3T3-L1 adipocytes and adipose tissue from mice. To dissociate oxidative stress from impaired oxidative phosphorylation and study whether mitochondrial oxidative stress per se can cause insulin resistance, we used mitochondria-targeted paraquat (MitoPQ) to generate superoxide within mitochondria without directly disrupting the respiratory chain. At ≤10 μm, MitoPQ specifically increased mitochondrial superoxide and hydrogen peroxide without altering mitochondrial respiration in intact cells. Under these conditions, MitoPQ impaired insulin-stimulated glucose uptake and glucose transporter 4 (GLUT4) translocation to the plasma membrane in both adipocytes and myotubes. MitoPQ recapitulated many features of insulin resistance found in other experimental models, including increased oxidants in mitochondria but not cytosol; a more profound effect on glucose transport than on other insulin-regulated processes, such as protein synthesis and lipolysis; an absence of overt defects in insulin signaling; and defective insulin- but not AMP-activated protein kinase (AMPK)-regulated GLUT4 translocation. We conclude that elevated mitochondrial oxidants rapidly impair insulin-regulated GLUT4 translocation and significantly contribute to insulin resistance and that MitoPQ is an ideal tool for studying the link between mitochondrial oxidative stress and regulated GLUT4 trafficking.

Published

2018

21. Methionine sulfoxide reductase B3 requires resolving cysteine residues for full activity and can act as a stereospecific methionine oxidase

Author

Cao, Zhenbo, Mitchell, Lorna, Hsia, Oliver, Scarpa, Miriam, Caldwell, Stuart T., Alfred, Arina D., Gennaris, Alexandra, Collet, Jean-Francois, Hartley, Richard C., and Bulleid, Neil J.

Abstract

The oxidation of methionine residues in proteins occurs during oxidative stress and can lead to an alteration in protein function. The enzyme methionine sulfoxide reductase reverses this modification. Here we characterise the mammalian enzyme methionine sulfoxide reductase B3. There are two splice variants of this enzyme that differ only in their N-terminal signal sequence, which directs the protein to either the ER or mitochondria. We demonstrate here that the enzyme can complement a bacterial strain which is dependent upon methionine sulfoxide reduction for growth, that the purified recombinant protein is enzymatically active showing stereospecificity towards R -methionine sulfoxide, and identify the active site and two resolving cysteine residues. The enzyme is efficiently recycled by thioredoxin only in the presence of both resolving cysteine residues. These results show that for this isoform of methionine sulfoxide reductase, the reduction cycle most likely proceeds through a three step process. This involves an initial sulfenylation of the active site thiol followed by the formation of an intra-chain disulfide with a resolving thiol group and completed by the reduction of this disulfide by a thioredoxin-like protein to regenerate the active site thiol. Interestingly the enzyme can also act as an oxidase catalysing the stereospecific formation of R -methionine sulfoxide. This result has important implications for the role of this enzyme in the reversible modification of ER and mitochondrial proteins.

Published

2018

22. The Mitochondria-Targeted Methylglyoxal Sequestering Compound, MitoGamide, Is Cardioprotective in the Diabetic Heart

Author

Tate, Mitchel, primary, Higgins, Gavin C., additional, De Blasio, Miles J., additional, Lindblom, Runa, additional, Prakoso, Darnel, additional, Deo, Minh, additional, Kiriazis, Helen, additional, Park, Min, additional, Baeza-Garza, Carlos D., additional, Caldwell, Stuart T., additional, Hartley, Richard C., additional, Krieg, Thomas, additional, Murphy, Michael P., additional, Coughlan, Melinda T., additional, and Ritchie, Rebecca H., additional

Published

2019

23. Selective mitochondrial superoxide generation in vivo is cardioprotective through hormesis

Author

Antonucci, Salvatore, primary, Mulvey, John F., additional, Burger, Nils, additional, Di Sante, Moises, additional, Hall, Andrew R., additional, Hinchy, Elizabeth C., additional, Caldwell, Stuart T., additional, Gruszczyk, Anja V., additional, Deshwal, Soni, additional, Hartley, Richard C., additional, Kaludercic, Nina, additional, Murphy, Michael P., additional, Di Lisa, Fabio, additional, and Krieg, Thomas, additional

Published

2019

24. Methionine sulfoxide reductase B3 requires resolving cysteine residues for full activity and can act as a stereospecific methionine oxidase.

Author

Zhenbo Cao, Mitchell, Lorna, Hsia, Oliver, Scarpa, Miriam, Caldwell, Stuart T., Alfred, Arina D., Gennaris, Alexandra, Collet, Jean-François, Hartley, Richard C., and Bulleid, Neil J.

Abstract

The oxidation of methionine residues in proteins occurs during oxidative stress and can lead to an alteration in protein function. The enzyme methionine sulfoxide reductase (Msr) reverses this modification. Here, we characterise the mammalian enzyme Msr B3. There are two splice variants of this enzyme that differ only in their N-terminal signal sequence, which directs the protein to either the endoplasmic reticulum (ER) or mitochondria. We demonstrate here that the enzyme can complement a bacterial strain, which is dependent on methionine sulfoxide reduction for growth, that the purified recombinant protein is enzymatically active showing stereospecificity towards R-methionine sulfoxide, and identify the active site and two resolving cysteine residues. The enzyme is efficiently recycled by thioredoxin only in the presence of both resolving cysteine residues. These results show that for this isoform of Msrs, the reduction cycle most likely proceeds through a three-step process. This involves an initial sulfenylation of the active site thiol followed by the formation of an intrachain disulfide with a resolving thiol group and completed by the reduction of this disulfide by a thioredoxin-like protein to regenerate the active site thiol. Interestingly, the enzyme can also act as an oxidase catalysing the stereospecific formation of R-methionine sulfoxide. This result has important implications for the role of this enzyme in the reversible modification of ER and mitochondrial proteins. [ABSTRACT FROM AUTHOR]

Published

2018

25. Photoactivated release of membrane impermeant sulfonates inside cells

Author

Filip Cvetko, John G. McCarron, Calum Wilson, Sean N O'Byrne, Michael P. Murphy, Stuart T. Caldwell, Richard C. Hartley, Caldwell, Stuart T [0000-0003-1604-3462], O'Byrne, Sean N [0000-0002-1880-0239], Wilson, Calum [0000-0003-2500-0632], Murphy, Michael P [0000-0003-1115-9618], McCarron, John G [0000-0002-3302-3984], Hartley, Richard C [0000-0003-1033-5405], and Apollo - University of Cambridge Repository

Subjects

Anions, Cell Membrane Permeability, Cell, 010402 general chemistry, 01 natural sciences, Catalysis, Phosphates, chemistry.chemical_compound, Coumarins, Materials Chemistry, medicine, Humans, QD, 010405 organic chemistry, Rhodamines, fungi, Metals and Alloys, food and beverages, General Chemistry, Photochemical Processes, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Chemistry, Sulfonate, Membrane, medicine.anatomical_structure, chemistry, Ceramics and Composites, Biophysics, Sulfonic Acids, HeLa Cells

Abstract

Photouncaging delivers compounds with high spatial and temporal control to induce or inhibit biological processes but the released compounds may diffuse out. We here demonstrate that sulfonate anions can be photocaged so that a membrane impermeable compound can enter cells, be uncaged by photoirradiation and trapped within the cell., Photocaged sulfonate delivers membrane impermeant compounds to cells.

Published

2021

26. Rapid and selective generation of H 2 S within mitochondria protects against cardiac ischemia-reperfusion injury.

Author

Miljkovic JL, Burger N, Gawel JM, Mulvey JF, Norman AAI, Nishimura T, Tsujihata Y, Logan A, Sauchanka O, Caldwell ST, Morris JL, Prime TA, Warrington S, Prudent J, Bates GR, Aksentijević D, Prag HA, James AM, Krieg T, Hartley RC, and Murphy MP

Abstract

Mitochondria-targeted H 2 S donors are thought to protect against acute ischemia-reperfusion (IR) injury by releasing H 2 S that decreases oxidative damage. However, the rate of H 2 S release by current donors is too slow to be effective upon administration following reperfusion. To overcome this limitation here we develop a mitochondria-targeted agent, MitoPerSulf that very rapidly releases H 2 S within mitochondria. MitoPerSulf is quickly taken up by mitochondria, where it reacts with endogenous thiols to generate a persulfide intermediate that releases H 2 S. MitoPerSulf is acutely protective against cardiac IR injury in mice, due to the acute generation of H 2 S that inhibits respiration at cytochrome c oxidase thereby preventing mitochondrial superoxide production by lowering the membrane potential. Mitochondria-targeted agents that rapidly generate H 2 S are a new class of therapy for the acute treatment of IR injury., (Copyright © 2022 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2022

27. Enhancing the Mitochondrial Uptake of Phosphonium Cations by Carboxylic Acid Incorporation.

Author

Pala L, Senn HM, Caldwell ST, Prime TA, Warrington S, Bright TP, Prag HA, Wilson C, Murphy MP, and Hartley RC

Abstract

There is considerable interest in developing drugs and probes targeted to mitochondria in order to understand and treat the many pathologies associated with mitochondrial dysfunction. The large membrane potential, negative inside, across the mitochondrial inner membrane enables delivery of molecules conjugated to lipophilic phosphonium cations to the organelle. Due to their combination of charge and hydrophobicity, quaternary triarylphosphonium cations rapidly cross biological membranes without the requirement for a carrier. Their extent of uptake is determined by the magnitude of the mitochondrial membrane potential, as described by the Nernst equation. To further enhance this uptake here we explored whether incorporation of a carboxylic acid into a quaternary triarylphosphonium cation would enhance its mitochondrial uptake in response to both the membrane potential and the mitochondrial pH gradient (alkaline inside). Accumulation of arylpropionic acid derivatives depended on both the membrane potential and the pH gradient. However, acetic or benzoic derivatives did not accumulate, due to their lowered pK a . Surprisingly, despite not being taken up by mitochondria, the phenylacetic or phenylbenzoic derivatives were not retained within mitochondria when generated within the mitochondrial matrix by hydrolysis of their cognate esters. Computational studies, supported by crystallography, showed that these molecules passed through the hydrophobic core of mitochondrial inner membrane as a neutral dimer. This finding extends our understanding of the mechanisms of membrane permeation of lipophilic cations and suggests future strategies to enhance drug and probe delivery to mitochondria., (Copyright © 2020 Pala, Senn, Caldwell, Prime, Warrington, Bright, Prag, Wilson, Murphy and Hartley.)

Published

2020

28. Mitochondrial oxidative stress causes insulin resistance without disrupting oxidative phosphorylation.

Author

Fazakerley DJ, Minard AY, Krycer JR, Thomas KC, Stöckli J, Harney DJ, Burchfield JG, Maghzal GJ, Caldwell ST, Hartley RC, Stocker R, Murphy MP, and James DE

Subjects

3T3-L1 Cells, Adenylate Kinase metabolism, Adipocytes metabolism, Animals, Electron Transport drug effects, Glucose metabolism, Glucose Transporter Type 4 metabolism, Herbicides pharmacology, Hydrogen Peroxide metabolism, Insulin metabolism, Male, Mice, Mice, Inbred C57BL, Mitochondria drug effects, Myoblasts metabolism, Oxygen Consumption drug effects, Paraquat toxicity, Peroxiredoxins metabolism, Protein Isoforms metabolism, Superoxides metabolism, Insulin Resistance, Mitochondria metabolism, Oxidative Phosphorylation

Abstract

Mitochondrial oxidative stress, mitochondrial dysfunction, or both have been implicated in insulin resistance. However, disentangling the individual roles of these processes in insulin resistance has been difficult because they often occur in tandem, and tools that selectively increase oxidant production without impairing mitochondrial respiration have been lacking. Using the dimer/monomer status of peroxiredoxin isoforms as an indicator of compartmental hydrogen peroxide burden, we provide evidence that oxidative stress is localized to mitochondria in insulin-resistant 3T3-L1 adipocytes and adipose tissue from mice. To dissociate oxidative stress from impaired oxidative phosphorylation and study whether mitochondrial oxidative stress per se can cause insulin resistance, we used mitochondria-targeted paraquat (MitoPQ) to generate superoxide within mitochondria without directly disrupting the respiratory chain. At ≤10 μm, MitoPQ specifically increased mitochondrial superoxide and hydrogen peroxide without altering mitochondrial respiration in intact cells. Under these conditions, MitoPQ impaired insulin-stimulated glucose uptake and glucose transporter 4 (GLUT4) translocation to the plasma membrane in both adipocytes and myotubes. MitoPQ recapitulated many features of insulin resistance found in other experimental models, including increased oxidants in mitochondria but not cytosol; a more profound effect on glucose transport than on other insulin-regulated processes, such as protein synthesis and lipolysis; an absence of overt defects in insulin signaling; and defective insulin- but not AMP-activated protein kinase (AMPK)-regulated GLUT4 translocation. We conclude that elevated mitochondrial oxidants rapidly impair insulin-regulated GLUT4 translocation and significantly contribute to insulin resistance and that MitoPQ is an ideal tool for studying the link between mitochondrial oxidative stress and regulated GLUT4 trafficking., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

29. Methionine sulfoxide reductase B3 requires resolving cysteine residues for full activity and can act as a stereospecific methionine oxidase.

Author

Cao Z, Mitchell L, Hsia O, Scarpa M, Caldwell ST, Alfred AD, Gennaris A, Collet JF, Hartley RC, and Bulleid NJ

Subjects

Catalysis, Catalytic Domain, Cysteine chemistry, Disulfides chemistry, Disulfides metabolism, Endoplasmic Reticulum chemistry, Endoplasmic Reticulum genetics, Methionine Sulfoxide Reductases chemistry, Mitochondria genetics, Oxidation-Reduction, Oxygenases chemistry, Protein Transport genetics, Recombinant Proteins chemistry, Thioredoxins chemistry, Thioredoxins metabolism, Methionine Sulfoxide Reductases genetics, Oxidative Stress genetics, Oxygenases genetics, Recombinant Proteins genetics

Abstract

The oxidation of methionine residues in proteins occurs during oxidative stress and can lead to an alteration in protein function. The enzyme methionine sulfoxide reductase (Msr) reverses this modification. Here, we characterise the mammalian enzyme Msr B3. There are two splice variants of this enzyme that differ only in their N-terminal signal sequence, which directs the protein to either the endoplasmic reticulum (ER) or mitochondria. We demonstrate here that the enzyme can complement a bacterial strain, which is dependent on methionine sulfoxide reduction for growth, that the purified recombinant protein is enzymatically active showing stereospecificity towards R -methionine sulfoxide, and identify the active site and two resolving cysteine residues. The enzyme is efficiently recycled by thioredoxin only in the presence of both resolving cysteine residues. These results show that for this isoform of Msrs, the reduction cycle most likely proceeds through a three-step process. This involves an initial sulfenylation of the active site thiol followed by the formation of an intrachain disulfide with a resolving thiol group and completed by the reduction of this disulfide by a thioredoxin-like protein to regenerate the active site thiol. Interestingly, the enzyme can also act as an oxidase catalysing the stereospecific formation of R -methionine sulfoxide. This result has important implications for the role of this enzyme in the reversible modification of ER and mitochondrial proteins., (© 2018 The Author(s).)

Published

2018