Protein Arginine Deiminases and Associated Citrullination: Physiological Functions and Diseases Associated with Dysregulation

Witalison, Erin E.; Thompson, Paul R.; Hofseth, Lorne J.

doi:10.2174/1389450116666150202160954

Cited by 241 publications

(268 citation statements)

References 107 publications

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“…As shown in Fig. 6B, the expression of PAD enzymes (estimated by the iBAQ approach) varied greatly between tissues consistent with earlier reports (8,48) and immunohistochemistry data available for the PAD enzymes in the Protein Atlas Project (25). For example, in brain, the expression of PAD2 is 1,000-fold higher than that of PAD4 and at least 5-fold higher than in other PAD2-expressing tissues.…”

Section: The Landscape Of Protein Citrullination Of Human Tissuessupporting

confidence: 89%

“…Five PAD isoforms have been found in humans, PAD1-4, and the catalytically inactive PAD6 (1), which are believed to have distinct tissue-specificities (2-6). PADcatalyzed citrullination has been implicated in many cellular processes such as terminal epidermal differentiation, apoptosis, central nervous system (CNS) stability, immune response, gene regulation, and embryonic development (7,8). The modification has gained more attention recently because its pathological relevance has been established by the identification of autoantibodies recognizing citrullinated proteins in rheumatoid arthritis (RA) patients (9).…”

Section: Introductionmentioning

confidence: 99%

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Mining the Human Tissue Proteome for Protein Citrullination

Lee

Wang

Wilhelm

et al. 2018

Molecular & Cellular Proteomics

175

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SummaryCitrullination is a post-translational modification of arginine catalyzed by five peptidylarginine deiminases (PADs) in humans. The loss of a positive charge may cause structural or functional alterations and while the modification has been linked to several diseases including rheumatoid arthritis and cancer, its physiological or pathophysiological roles remain largely unclear. In part this is owing to limitations in available methodology able to robustly enrich, detect and localize the modification. As a result, only few citrullination sites have been identified on human proteins with high confidence. In this study, we mined data from mass spectrometry-based deep proteomic profiling of 30 human tissues to identify citrullination sites on endogenous proteins. Database searching of ~70 million tandem mass spectra yielded ~13,000 candidate spectra which were further triaged by spectrum quality metrics and the detection of the specific neutral loss of isocyanic acid from citrullinated peptides to reduce false positives. Because citrullination is easily confused with deamidation, we synthetized ~2,200 citrullinated and 1,300 deamidated peptides to build a library of reference spectra. This led to the validation of 375 citrullination sites on 209 human proteins. Further analysis showed that >80% of the identified modifications sites were new and for 56% of the proteins, citrullination was detected for the first time. Sequence motif analysis revealed a strong preference for Asp and Gly, residues around the citrullination site. Interestingly, while the modification was detected in 26 human tissues with the highest levels found in brain and lung, citrullination levels did not correlate well with protein expression of the PAD enzymes.Even though the current work represents the largest survey of protein citrullination to date, the modification was mostly detected on high abundant proteins arguing that the development of specific enrichment methods would be required in order to study the full extent of cellular protein citrullination.

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Section: The Landscape Of Protein Citrullination Of Human Tissuessupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Mining the Human Tissue Proteome for Protein Citrullination

Lee

Wang

Wilhelm

et al. 2018

Molecular & Cellular Proteomics

175

View full text Add to dashboard Cite

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“…While PADs play physiological roles [39], their dysregulation is detected in various pathologies [40,41,42,43,44]. Pharmacological PAD-inhibition has shown promising results in cancer models both in vitro [45,46] and in vivo [43,47], as well as in animal models of various autoimmune diseases [48,49,50,51,52], neuronal injury [53], hypoxia [54], and atherosclerosis [55]. …”

Section: Introductionmentioning

confidence: 99%

Peptidylarginine Deiminases—Roles in Cancer and Neurodegeneration and Possible Avenues for Therapeutic Intervention via Modulation of Exosome and Microvesicle (EMV) Release?

Lange

Gallagher

Kholia

et al. 2017

IJMS

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Exosomes and microvesicles (EMVs) are lipid bilayer-enclosed structures released from cells and participate in cell-to-cell communication via transport of biological molecules. EMVs play important roles in various pathologies, including cancer and neurodegeneration. The regulation of EMV biogenesis is thus of great importance and novel ways for manipulating their release from cells have recently been highlighted. One of the pathways involved in EMV shedding is driven by peptidylarginine deiminase (PAD) mediated post-translational protein deimination, which is calcium-dependent and affects cytoskeletal rearrangement amongst other things. Increased PAD expression is observed in various cancers and neurodegeneration and may contribute to increased EMV shedding and disease progression. Here, we review the roles of PADs and EMVs in cancer and neurodegeneration.

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“…(2) Type I PRMTs then further modify the same nitrogen to generate asymmetrically dimethylated (aDMA) arginine, whereas (3) type II PRMTs modify the second nitrogen group to generate symmetrically dimethylated (sDMA) arginine. aDMA/sDMA PTMs were considered irreversible and could only be 'blocked' by (4) deimination to citrulline by peptidyl arginine deiminases (PADs) [95,96] but (5) PAD4 is suggested to also act on MMA to 'reverse' monobut not dimethylation. Also Jumonji domain-containing protein (JMJD) 6 catalyses (6) the conversion of aDMA, sDMA or MMA to arginine [97,98].…”

Section: Lysine Acetylationmentioning

confidence: 99%

Modulation of the cytoplasmic functions of mammalian post-transcriptional regulatory proteins by methylation and acetylation: a key layer of regulation waiting to be uncovered?

Blee

Gray

Brook

2015

Biochemical Society Transactions

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Post-transcriptional control of gene expression is critical for normal cellular function and viability and many of the proteins that mediate post-transcriptional control are themselves subject to regulation by posttranslational modification (PTM), e.g. phosphorylation. However, proteome-wide studies are revealing new complexities in the PTM status of mammalian proteins, in particular large numbers of novel methylated and acetylated residues are being identified. Here we review studied examples of methylation/acetylationdependent regulation of post-transcriptional regulatory protein (PTRP) function and present collated PTM data that points to the huge potential for regulation of mRNA fate by these PTMs.

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Protein Arginine Deiminases and Associated Citrullination: Physiological Functions and Diseases Associated with Dysregulation

Cited by 241 publications

References 107 publications

Mining the Human Tissue Proteome for Protein Citrullination

Mining the Human Tissue Proteome for Protein Citrullination

Peptidylarginine Deiminases—Roles in Cancer and Neurodegeneration and Possible Avenues for Therapeutic Intervention via Modulation of Exosome and Microvesicle (EMV) Release?

Modulation of the cytoplasmic functions of mammalian post-transcriptional regulatory proteins by methylation and acetylation: a key layer of regulation waiting to be uncovered?

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