Browsing by Subject "Post-translational modifications"

Now showing 1 - 6 of 6
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    Advancing the Metabolic Dysfunction-Associated Steatotic Liver Disease Proteome: A Post-Translational Outlook
    (MDPI, 2025-03-12) Chowdhury, Kushan; Das, Debajyoti; Huang, Menghao; Biochemistry and Molecular Biology, School of Medicine
    Metabolic dysfunction-associated steatotic liver disease (MASLD) is a prevalent liver disorder with limited treatment options. This review explores the role of post-translational modifications (PTMs) in MASLD pathogenesis, highlighting their potential as therapeutic targets. We discuss the impact of PTMs, including their phosphorylation, ubiquitylation, acetylation, and glycosylation, on key proteins involved in MASLD, drawing on studies that use both human subjects and animal models. These modifications influence various cellular processes, such as lipid metabolism, inflammation, and fibrosis, contributing to disease progression. Understanding the intricate PTM network in MASLD offers the potential for developing novel therapeutic strategies that target specific PTMs to modulate protein function and alleviate disease pathology. Further research is needed to fully elucidate the complexity of PTMs in MASLD and translate these findings into effective clinical applications.
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    Cardiac sodium channel palmitoylation regulates channel availability and myocyte excitability with implications for arrhythmia generation
    (Nature Publishing Group, 2016-06-23) Pei, Zifan; Xiao, Yucheng; Meng, Jingwei; Hudmon, Andy; Cummins, Theodore R.; Department of Pharmacology and Toxicology, IU School of Medicine
    Cardiac voltage-gated sodium channels (Nav1.5) play an essential role in regulating cardiac electric activity by initiating and propagating action potentials in the heart. Altered Nav1.5 function is associated with multiple cardiac diseases including long-QT3 and Brugada syndrome. Here, we show that Nav1.5 is subject to palmitoylation, a reversible post-translational lipid modification. Palmitoylation increases channel availability and late sodium current activity, leading to enhanced cardiac excitability and prolonged action potential duration. In contrast, blocking palmitoylation increases closed-state channel inactivation and reduces myocyte excitability. We identify four cysteines as possible Nav1.5 palmitoylation substrates. A mutation of one of these is associated with cardiac arrhythmia (C981F), induces a significant enhancement of channel closed-state inactivation and ablates sensitivity to depalmitoylation. Our data indicate that alterations in palmitoylation can substantially control Nav1.5 function and cardiac excitability and this form of post-translational modification is likely an important contributor to acquired and congenital arrhythmias.
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    Distinctive Properties and Powerful Neuromodulation of Nav1.6 Sodium Channels Regulates Neuronal Excitability
    (MDPI, 2021-06-25) Zybura, Agnes; Hudmon, Andy; Cummins, Theodore R.; Biology, School of Science
    Voltage-gated sodium channels (Navs) are critical determinants of cellular excitability. These ion channels exist as large heteromultimeric structures and their activity is tightly controlled. In neurons, the isoform Nav1.6 is highly enriched at the axon initial segment and nodes, making it critical for the initiation and propagation of neuronal impulses. Changes in Nav1.6 expression and function profoundly impact the input-output properties of neurons in normal and pathological conditions. While mutations in Nav1.6 may cause channel dysfunction, aberrant changes may also be the result of complex modes of regulation, including various protein-protein interactions and post-translational modifications, which can alter membrane excitability and neuronal firing properties. Despite decades of research, the complexities of Nav1.6 modulation in health and disease are still being determined. While some modulatory mechanisms have similar effects on other Nav isoforms, others are isoform-specific. Additionally, considerable progress has been made toward understanding how individual protein interactions and/or modifications affect Nav1.6 function. However, there is still more to be learned about how these different modes of modulation interact. Here, we examine the role of Nav1.6 in neuronal function and provide a thorough review of this channel’s complex regulatory mechanisms and how they may contribute to neuromodulation.
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    Experimental Evidence for Phosphorylation-Driven Allosteric Regulation of Alpha Synuclein Function
    (bioRxiv, 2025-02-26) Dollar, Ashlyn N.; Webb, Ian K.; Chemistry and Chemical Biology, School of Science
    Phosphorylation of serine 129 (pS129) in the intrinsically disordered protein alpha synuclein has long been associated with neurodegenerative disease. In the past several years, the functional relevance of pS219 has been uncovered by electrophysiology, immunoprecipitation, and proteomics as intricately connected with neurotransmitter release and synaptic vesicle (SV) cycling. Unexpectedly, binding to SNARE complex proteins VAMP-2 and synapsin only occurs with phosphorylation-competent alpha synuclein. The VAMP-2 binding domain has been shown to be residues 96-110, which does not include the phosphorylated residue, hinting at allosteric regulation of alpha synuclein protein-protein interactions by pS129. Within this study, cross-linking, covalent labeling, and collision induced unfolding of alpha synuclein and pS129 - as well as an additional encountered form in the brain, oxidized-M1, M5, M116, M127 alpha synuclein - are studied utilizing tandem mass spectrometry. Collision induced unfolding of proteins gives a fingerprint of the structures' relative compactness and stabilities of various conformations. Covalent labeling of proteins identifies solvent accessible residues and reveals the hydrophobicity (or hydrophilicity) of their microenvironment, while cross-linking of proteins maps the proximity of residue pairs. The combination of collision induced unfolding, covalent labeling, and cross-linking show unequivocally that phosphorylated-S129 alpha synuclein results in a more stable, more compact form. Our results provide evidence of an extensively folded amphipathic region that interacts strongly with the VAMP-2 binding domain. The phosphorylation-induced folding of the amphipathic region likely tunes other protein-protein interactions and interactions with SVs and membranes.
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    Identification of nonhistone substrates of the lysine methyltransferase PRDM9
    (Elsevier, 2023) Hanquier, Jocelyne N.; Sanders, Kenidi; Berryhill, Christine A.; Sahoo, Firoj K.; Hudmon, Andy; Vilseck, Jonah Z.; Cornett, Evan M.; Biochemistry and Molecular Biology, School of Medicine
    Lysine methylation is a dynamic, posttranslational mark that regulates the function of histone and nonhistone proteins. Many of the enzymes that mediate lysine methylation, known as lysine methyltransferases (KMTs), were originally identified to modify histone proteins but have also been discovered to methylate nonhistone proteins. In this work, we investigate the substrate selectivity of the KMT PRDM9 to identify both potential histone and nonhistone substrates. Though normally expressed in germ cells, PRDM9 is significantly upregulated across many cancer types. The methyltransferase activity of PRDM9 is essential for double-strand break formation during meiotic recombination. PRDM9 has been reported to methylate histone H3 at lysine residues 4 and 36; however, PRDM9 KMT activity had not previously been evaluated on nonhistone proteins. Using lysine-oriented peptide libraries to screen potential substrates of PRDM9, we determined that PRDM9 preferentially methylates peptide sequences not found in any histone protein. We confirmed PRDM9 selectivity through in vitro KMT reactions using peptides with substitutions at critical positions. A multisite λ-dynamics computational analysis provided a structural rationale for the observed PRDM9 selectivity. The substrate selectivity profile was then used to identify putative nonhistone substrates, which were tested by peptide spot array, and a subset was further validated at the protein level by in vitro KMT assays on recombinant proteins. Finally, one of the nonhistone substrates, CTNNBL1, was found to be methylated by PRDM9 in cells.
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    Modulating the modulators: regulation of protein arginine methyltransferases by post-translational modifications
    (Elsevier, 2020-09) Hartley, Antja-Voy; Lu, Tao; Pharmacology and Toxicology, School of Medicine
    The therapeutic potential of targeting protein arginine methyltransferases (PRMTs) is inextricably linked to their key roles in various cellular functions, including splicing, proliferation, cell cycle regulation, differentiation, and DNA damage signaling. Unsurprisingly, the development of inhibitors against these enzymes has become a rapidly expanding research area. However, effective targeting of PRMTs requires a deeper understanding of the mechanistic details behind their regulation at multiple levels, involving those mechanisms that alter their activity, interactions, and localization. Recently, post-translational modifications (PTMs) of PRMTs have emerged as another crucial aspect of this regulation. Here, we review the regulatory role of PTMs in the activity and function of PRMTs, with emphasis on the contribution of these PTMs to pathological states, such as cancer.