ARTD10/PARP10 Induces ADP-Ribosylation of GAPDH and Recruits GAPDH into Cytosolic Membrane-Free Cell Bodies When Overexpressed in Mammalian Cells

Mayo, Emilia; Fabrizio, Gaia; Scarpa, Emanuele Salvatore; Stilla, Annalisa; Dani, Nadia; Chiacchiera, Fulvio; Kleine, H. O.; Attanasio, Francesca; Lüscher, Bernhard; Girolamo, Maria Di

doi:10.3390/challe9010022

Cited by 8 publications

(9 citation statements)

References 48 publications

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“…Nonetheless, potential functions of ADP-ribosylation in the cytoplasm are rather poorly described. The best-studied ARTDs localizing to the cytoplasm are ARTD10, ARTD12, ARTD15 and the tankyrases (TNKs) [95,96,97,98,99,100]. ARTD10 and the TNKs have been linked to cytoplasmic metabolic processes, while the other cytoplasmic ARTDs have thus far not been directly associated with cell/carbohydrate metabolism.…”

Section: Cytoplasmic Crosstalk Of Adp-ribosylation and The Carbohymentioning

confidence: 99%

“…ARTD10 and the TNKs have been linked to cytoplasmic metabolic processes, while the other cytoplasmic ARTDs have thus far not been directly associated with cell/carbohydrate metabolism. ARTD12 localizes to the Golgi and is involved in protein sorting and trafficking [95,96], while ARTD15 localizes to the ER and has been linked to the unfolded protein response [97,98]. For more detailed information about the function of other (cytoplasmic) ARTs, the reader is referred to other reviews [101].…”

Section: Cytoplasmic Crosstalk Of Adp-ribosylation and The Carbohymentioning

confidence: 99%

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Regulation of Glucose Metabolism by NAD+ and ADP-Ribosylation

Hopp

Grüter

Hottiger

2019

Cells

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Cells constantly adapt their metabolic pathways to meet their energy needs and respond to nutrient availability. During the last two decades, it has become increasingly clear that NAD+, a coenzyme in redox reactions, also mediates several ubiquitous cell signaling processes. Protein ADP-ribosylation is a post-translational modification that uses NAD+ as a substrate and is best known as part of the genotoxic stress response. However, there is increasing evidence that NAD+-dependent ADP-ribosylation regulates other cellular processes, including metabolic pathways. In this review, we will describe the compartmentalized regulation of NAD+ biosynthesis, consumption, and regeneration with a particular focus on the role of ADP-ribosylation in the regulation of glucose metabolism in different cellular compartments.

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Section: Cytoplasmic Crosstalk Of Adp-ribosylation and The Carbohymentioning

confidence: 99%

Section: Cytoplasmic Crosstalk Of Adp-ribosylation and The Carbohymentioning

confidence: 99%

Regulation of Glucose Metabolism by NAD+ and ADP-Ribosylation

Hopp

Grüter

Hottiger

2019

Cells

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“…We have recently provided evidence that ARTD10 interacts with and mono-ADP-ribosylates the glyceraldehyde 3-phosphate dehydrogenase (GAPDH), a glycolytic enzyme that links metabolic activity to various cellular processes, including cell survival and proliferation [160]. The co-localization of GAPDH and ARTD10 occurs in well-defined cytosolic cell bodies, which we have shown to be rounded membrane-free structures.…”

Section: Artd10mentioning

confidence: 91%

“…Inhibition of ARTD10 activity resulted in the release of GAPDH from these cytosolic cell bodies, indicating that the catalytic activity of ARTD10 is required to recruit GAPDH, but it is not required to induce the formation of these cell bodies. Moreover, the dehydrogenase activity of GAPDH appears not to be regulated by its ADP-ribosylation, thus leading to hypothesis that ADP-ribosylation is important for the recruitment of GAPDH into cell bodies [160].…”

Section: Artd10mentioning

confidence: 99%

The ADP-Ribosyl-Transferases Diphtheria Toxin-Like (ARTDs) Family: An Overview

Girolamo¹,

Fabrizio²

2018

Challenges

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Poly-ADP-ribosylation is a post-translational modification that occurs in multicellular organisms, including plants and some lower unicellular eukaryotes. The founding member of the PARP family is PARP1. To date, 17 members of the PARP family have been identified, which differ from each other in terms of domain organization, transmodification targets, cellular localization, and biological functions. In recent years, considering structural and biochemical features of the different members of the PARP family, a new classification has been proposed. Thus, enzymes firstly classified as PARP are now named diphtheria-toxin-like ARTs, abbreviated to ARTDs, in accordance with the prototype bacterial toxin that their structural aspects resemble, with numbers indicating the different proteins of the family. The 17 human ARTD enzymes can be divided on the basis of their catalytic activity into polymerases (ARTD1-6), mono-ADP-ribosyl-transferases (ARTD7-17), and the inactive ARTD13. In recent years, ADP-ribosylation was intensively studied, and research was dominated by studies focusing on the role of this modification and its implication on various cellular processes. The aim of this review is to provide a general overview of the ARTD enzymes, with a special focus on mono-ARTDs.

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“…In total, 58 proteins were identified as potential PARP10 substrates ( Fig. 4a, Supplementary Data 12), some of which already known, such as ILF2, ILF3, IPO4 and PUM1 42 as well as GAPDH 43 . Melting curves for some of the putative substrates are shown in Fig.…”

Section: Siesta Identified and Ranked Many Novel Putative Substrates mentioning

confidence: 99%

System-wide identification and prioritization of enzyme substrates by thermal analysis (SIESTA)

Saei

Beusch

Sabatier

et al. 2018

Preprint

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Despite the immense importance of enzyme-substrate reactions, there is a lack of generic and unbiased tools for identifying and prioritizing substrate proteins which are modulated in the structural and functional levels through modification. Here we describe a high-throughput unbiased proteomic method called System-wide Identification and prioritization of Enzyme Substrates by Thermal Analysis (SIESTA). The approach assumes that enzymatic posttranslational modification of substrate proteins might change their thermal stability. SIESTA successfully identifies several known and novel substrate candidates for selenoprotein thioredoxin reductase 1, protein kinase B (AKT1) and poly-(ADP-ribose) polymerase-10 systems in up to a depth of 7179 proteins. Wider application of SIESTA can enhance our understanding of the role of enzymes in homeostasis and disease, open new opportunities in investigating the effect of PTMs on signal transduction, and facilitate drug discovery.

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ARTD10/PARP10 Induces ADP-Ribosylation of GAPDH and Recruits GAPDH into Cytosolic Membrane-Free Cell Bodies When Overexpressed in Mammalian Cells

Cited by 8 publications

References 48 publications

Regulation of Glucose Metabolism by NAD+ and ADP-Ribosylation

Regulation of Glucose Metabolism by NAD+ and ADP-Ribosylation

The ADP-Ribosyl-Transferases Diphtheria Toxin-Like (ARTDs) Family: An Overview

System-wide identification and prioritization of enzyme substrates by thermal analysis (SIESTA)

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