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  • Küçük Resim Yok
    Öğe
    Computational study of the activation mechanism of wild-type parkin and its clinically relevant mutant
    (2025) Cinviz, Zeynep Nur; Şensoy, Özge
    Parkinson's disease (PD) is the second most prevalent neurodegenerative disorder. It impairs the control of movement and balance. Parkin mutations worsen the symptoms in sporadic cases and cause the early onset of the disease. Therefore, recent efforts have focused on the rescue of defective parkin by engineered proteins or small-molecule activators to enhance parkin activation. These attempts require holistic understanding of the multistep activation mechanism and molecular effects of disease-associated mutations. Hereby, we provided a comprehensive analysis of the activation mechanism of parkin and a clinically relevant mutant, parkinS167N, using molecular dynamics simulations based on the following crystal structures: (1) parkin, (2) parkin/pUb (phosphorylated Ubiquitin), (3) pparkin/pUb, and (4) pparkin/pUb/UbcH7-Ub. Each of these represents an individual step in the activation process. We showed that the mutation impacted the dynamics of not only the RING0 domain, where it is localized, but also the RING2, Ubl, and IBR domains. We identified residues participating in the allosteric interaction network involved in parkin activation. Some of them are mutated in PD-associated parkin variants. The RING0 domain provides a binding interface with various proteins, so understanding problems associated with the mutation paves the way to the discovery of effective engineered proteins or small molecules that activate mutant parkin.
  • Küçük Resim
    Öğe
    Residues in the fructose-binding pocket are required for ketohexokinase-A activity
    (2024) Ferreira, Juliana C.; Villanueva, Adrian J.; Fadl, Samar; Al Adem, Kenana; Cinviz, Zeynep Nur; Nedyalkova, Lyudmila; Cardoso, Thyago H.S.; Andrade, Mario Edson; Saksena, Nitin K.; Şensoy, Özge; Rabeh, Wael M.
    Excessive fructose consumption is a primary contributor to the global surges in obesity, cancer, and metabolic syndrome. Fructolysis is not robustly regulated and is initiated by ketohexokinase (KHK). In this study, we determined the crystal structure of KHK-A, one of two human isozymes of KHK, in the apo-state at 1.85 Å resolution, and we investigated the roles of residues in the fructose-binding pocket by mutational analysis. Introducing alanine at D15, N42, or N45 inactivated KHK-A, whereas mutating R141 or K174 reduced activity and thermodynamic stability. Kinetic studies revealed that the R141A and K174A mutations reduced fructose affinity by 2- to 4-fold compared to WT KHK-A, without affecting ATP affinity. Molecular dynamics simulations provided mechanistic insights into the potential roles of the mutated residues in ligand coordination and the maintenance of an open state in one monomer and a closed state in the other. Protein–protein interactome analysis indicated distinct expression patterns and downregulation of partner proteins in different tumor tissues, warranting a reevaluation of KHK's role in cancer development and progression. The connections between different cancer genes and the KHK signaling pathway suggest that KHK is a potential target for preventing cancer metastasis. This study enhances our understanding of KHK-A's structure and function and offers valuable insights into potential targets for developing treatments for obesity, cancer, and metabolic syndrome.