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Structural and functional fine mapping of cysteines in mammalian glutaredoxin reveal their differential oxidation susceptibility

Author

Listed:
  • Elizabeth M. Corteselli

    (University of Vermont Larner College of Medicine)

  • Mona Sharafi

    (University of Vermont)

  • Robert Hondal

    (University of Vermont)

  • Maximilian MacPherson

    (University of Vermont Larner College of Medicine)

  • Sheryl White

    (University of Vermont Larner College of Medicine)

  • Ying-Wai Lam

    (University of Vermont)

  • Clarissa Gold

    (University of Vermont)

  • Allison M. Manuel

    (University of Vermont Larner College of Medicine)

  • Albert Vliet

    (University of Vermont Larner College of Medicine)

  • Severin T. Schneebeli

    (Purdue University)

  • Vikas Anathy

    (University of Vermont Larner College of Medicine)

  • Jianing Li

    (Purdue University)

  • Yvonne M. W. Janssen-Heininger

    (University of Vermont Larner College of Medicine)

Abstract

Protein-S-glutathionylation is a post-translational modification involving the conjugation of glutathione to protein thiols, which can modulate the activity and structure of key cellular proteins. Glutaredoxins (GLRX) are oxidoreductases that regulate this process by performing deglutathionylation. However, GLRX has five cysteines that are potentially vulnerable to oxidative modification, which is associated with GLRX aggregation and loss of activity. To date, GLRX cysteines that are oxidatively modified and their relative susceptibilities remain unknown. We utilized molecular modeling approaches, activity assays using recombinant GLRX, coupled with site-directed mutagenesis of each cysteine both individually and in combination to address the oxidizibility of GLRX cysteines. These approaches reveal that C8 and C83 are targets for S-glutathionylation and oxidation by hydrogen peroxide in vitro. In silico modeling and experimental validation confirm a prominent role of C8 for dimer formation and aggregation. Lastly, combinatorial mutation of C8, C26, and C83 results in increased activity of GLRX and resistance to oxidative inactivation and aggregation. Results from these integrated computational and experimental studies provide insights into the relative oxidizability of GLRX’s cysteines and have implications for the use of GLRX as a therapeutic in settings of dysregulated protein glutathionylation.

Suggested Citation

  • Elizabeth M. Corteselli & Mona Sharafi & Robert Hondal & Maximilian MacPherson & Sheryl White & Ying-Wai Lam & Clarissa Gold & Allison M. Manuel & Albert Vliet & Severin T. Schneebeli & Vikas Anathy &, 2023. "Structural and functional fine mapping of cysteines in mammalian glutaredoxin reveal their differential oxidation susceptibility," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-39664-2
    DOI: 10.1038/s41467-023-39664-2
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    References listed on IDEAS

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    1. Patricia Begas & Linda Liedgens & Anna Moseler & Andreas J. Meyer & Marcel Deponte, 2017. "Glutaredoxin catalysis requires two distinct glutathione interaction sites," Nature Communications, Nature, vol. 8(1), pages 1-13, April.
    2. Linda Liedgens & Jannik Zimmermann & Lucas Wäschenbach & Fabian Geissel & Hugo Laporte & Holger Gohlke & Bruce Morgan & Marcel Deponte, 2020. "Quantitative assessment of the determinant structural differences between redox-active and inactive glutaredoxins," Nature Communications, Nature, vol. 11(1), pages 1-18, December.
    3. Daniel Trnka & Anna D. Engelke & Manuela Gellert & Anna Moseler & Md Faruq Hossain & Tobias T. Lindenberg & Luca Pedroletti & Benjamin Odermatt & João V. Souza & Agnieszka K. Bronowska & Tobias P. Dic, 2020. "Molecular basis for the distinct functions of redox-active and FeS-transfering glutaredoxins," Nature Communications, Nature, vol. 11(1), pages 1-12, December.
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