scholarly journals Altered Plant and Nodule Development and Protein S-Nitrosylation in Lotus japonicus Mutants Deficient in S-Nitrosoglutathione Reductases

2019 ◽  
Vol 61 (1) ◽  
pp. 105-117 ◽  
Author(s):  
Manuel A Matamoros ◽  
Maria C Cutrona ◽  
Stefanie Wienkoop ◽  
Juan C Begara-Morales ◽  
Niels Sandal ◽  
...  
Keyword(s):  
Protein Function ◽  
Stress Protein ◽  
Lotus Japonicus ◽  
Protein S ◽  
Shotgun Proteomics ◽  
Nodule Development ◽  
Post Translational Modification ◽  
Cysteine Oxidation ◽  
No Donor

Abstract Nitric oxide (NO) is a crucial signaling molecule that conveys its bioactivity mainly through protein S-nitrosylation. This is a reversible post-translational modification (PTM) that may affect protein function. S-nitrosoglutathione (GSNO) is a cellular NO reservoir and NO donor in protein S-nitrosylation. The enzyme S-nitrosoglutathione reductase (GSNOR) degrades GSNO, thereby regulating indirectly signaling cascades associated with this PTM. Here, the two GSNORs of the legume Lotus japonicus, LjGSNOR1 and LjGSNOR2, have been functionally characterized. The LjGSNOR1 gene is very active in leaves and roots, whereas LjGSNOR2 is highly expressed in nodules. The enzyme activities are regulated in vitro by redox-based PTMs. Reducing conditions and hydrogen sulfide-mediated cysteine persulfidation induced both activities, whereas cysteine oxidation or glutathionylation inhibited them. Ljgsnor1 knockout mutants contained higher levels of S-nitrosothiols. Affinity chromatography and subsequent shotgun proteomics allowed us to identify 19 proteins that are differentially S-nitrosylated in the mutant and the wild-type. These include proteins involved in biotic stress, protein degradation, antioxidant protection and photosynthesis. We propose that, in the mutant plants, deregulated protein S-nitrosylation contributes to developmental alterations, such as growth inhibition, impaired nodulation and delayed flowering and fruiting. Our results highlight the importance of GSNOR function in legume biology.

Abstract 15523: Dynamic Protein S-palmitoylation Contributes to Cardiac Remodeling During Aging With Chronic Hypertension

Circulation ◽  
2020 ◽  
Vol 142 (Suppl_3) ◽  
Author(s):  
Madeleine R Miles ◽  
John Seo ◽  
Zachary Wilson ◽  
Min Jiang ◽  
Gea-ny Tseng
Keyword(s):  
Heart Failure ◽  
Protein Function ◽  
Ventricular Myocytes ◽  
Wide Spectrum ◽  
Enrichment Analysis ◽  
Protein S ◽  
Ventricular Myocardium ◽  
Chronic Hypertension ◽  
Post Translational Modification ◽  
Α Subunit

Introduction: More that 10% of human proteins can be S-palmitoylated, a post-translational modification (PTM) whereby palmitoyl chains are covalently linked to cysteine thiol groups. S-palmitoylation influences protein trafficking, distribution and function. There is no information on the scope of protein S-palmitoylation in the heart, or how this enzyme-mediated reversible PTM is regulated. Hypothesis: S-palmitoylation occurs to a wide spectrum of proteins in cardiomyocytes, and is coordinated by membrane-embedded palmitoylating (DHHC) enzymes. DHHC enzymes are subject to remodeling during chronic hypertension. Methods: We used resin-assisted capture to purify S-palmitoylated proteins from ventricular myocardium of 3 species: human, dog, and rat. We used global unbiased proteomic search to identify S-palmitoylated proteins. We validated DHHC antibodies and used them to monitor protein level and subcellular distribution of native DHHC enzymes in ventricular myocytes. Results: We built a 'composite' cardiac palmitome composed of 462 S-palmitoylatable proteins identified in ≥ 2 species-specific cardiac palmitomes. Enrichment analysis based on GO term 'cellular component' indicated that they are mainly involved in cell-cell and cell-substrate associations, sarcolemma and sarcomere organization, vesicular trafficking, G-protein function, ATP-dependent transmembrane transport, and mitochondria inner and outer membrane organization. Among the 23 DHHC enzymes, we detected ten in hearts across species. In ventricular myocytes with well-defined subcellular compartments, DHHC enzymes exhibited distinct distribution patterns: peripheral sarcolemma (DHHC1), M-lines (DHHC2), Z-lines (DHHC5), vesicles (DHHC7) and intercalated disc (DHHC9). In aging spontaneously hypertensive rats (a model of chronic hypertension, some in heart failure), seven DHHC enzymes were upregulated in the heart, accompanied by a higher degree of S-palmitoylation of CaMK II, caveolin3, Na/Ca exchanger, and Na/K pump α-subunit. Conclusion: S-palmitoylation is involved in most, if not all, aspects of cardiomyocyte function. Palmitoylation dysregulation may contribute to pathological progression in hypertrophy leading to heart failure.

Effects of reactive oxygen and nitrogen metabolites on MCP-1-induced monocyte chemotactic activity in vitro

1999 ◽  
Vol 277 (3) ◽  
pp. L543-L549 ◽  
Author(s):  
Etsuro Sato ◽  
Keith L. Simpson ◽  
Matthew B. Grisham ◽  
Sekiya Koyama ◽  
Richard A. Robbins
Keyword(s):  
Protein Function ◽  
Inhibitory Effect ◽  
Chemotactic Activity ◽  
Dependent Manner ◽  
No Donor ◽  
Monocyte Chemoattractant Protein 1 ◽  
Dependent Inhibition ◽  
Monocyte Chemotaxis ◽  
Dose Dependent

Peroxynitrite, an oxidant generated by the interaction between superoxide and nitric oxide (NO), can nitrate tyrosine residues, resulting in compromised protein function. Monocyte chemoattractant protein-1 (MCP-1) is a chemokine that attracts monocytes and has a tyrosine residue critical for function. We hypothesized that peroxynitrite would alter MCP-1 activity. Peroxynitrite attenuated MCP-1-induced monocyte chemotactic activity (MCA) in a dose-dependent manner ( P < 0.05) but did not attenuate leukotriene B4 or complement-activated serum MCA. The reducing agents dithionite, deferoxamine, and dithiothreitol reversed the MCA inhibition by peroxynitrite, and exogenous l-tyrosine abrogated the inhibition by peroxynitrite. PAPA-NONOate, an NO donor, or superoxide generated by xanthine and xanthine oxidase did not show an inhibitory effect on MCA induced by MCP-1. The peroxynitrite generator 3-morpholinosydnonimine caused a concentration-dependent inhibition of MCA by MCP-1. Peroxynitrite reduced MCP-1 binding to monocytes and resulted in nitrotyrosine formation. These findings are consistent with nitration of tyrosine by peroxynitrite, with subsequent inhibition of MCP-1 binding to monocytes, and suggest that peroxynitrite may play a role in regulation of MCP-1-induced monocyte chemotaxis.

scholarly journals SET7/9-dependent methylation of ARTD1 at K508 stimulates poly-ADP-ribose formation after oxidative stress

Open Biology ◽  
2013 ◽  
Vol 3 (10) ◽  
pp. 120173 ◽  
Author(s):  
Ingrid Kassner ◽  
Anneli Andersson ◽  
Monika Fey ◽  
Martin Tomas ◽  
Elisa Ferrando-May ◽  
...  
Keyword(s):  
Oxidative Stress ◽  
Protein Interactions ◽  
Protein Function ◽  
Dependent Manner ◽  
Protein Protein Interactions ◽  
Post Translational Modification ◽  
Target Proteins ◽  
Protein Methyltransferase

ADP-ribosyltransferase diphtheria toxin-like 1 (ARTD1, formerly PARP1) is localized in the nucleus, where it ADP-ribosylates specific target proteins. The post-translational modification (PTM) with a single ADP-ribose unit or with polymeric ADP-ribose (PAR) chains regulates protein function as well as protein–protein interactions and is implicated in many biological processes and diseases. SET7/9 (Setd7, KMT7) is a protein methyltransferase that catalyses lysine monomethylation of histones, but also methylates many non-histone target proteins such as p53 or DNMT1. Here, we identify ARTD1 as a new SET7/9 target protein that is methylated at K508 in vitro and in vivo . ARTD1 auto-modification inhibits its methylation by SET7/9, while auto-poly-ADP-ribosylation is not impaired by prior methylation of ARTD1. Moreover, ARTD1 methylation by SET7/9 enhances the synthesis of PAR upon oxidative stress in vivo . Furthermore, laser irradiation-induced PAR formation and ARTD1 recruitment to sites of DNA damage in a SET7/9-dependent manner. Together, these results reveal a novel mechanism for the regulation of cellular ARTD1 activity by SET7/9 to assure efficient PAR formation upon cellular stress.

scholarly journals Lysine methylation is an endogenous post-translational modification of tau protein in human brain and a modulator of aggregation propensity

2014 ◽  
Vol 462 (1) ◽  
pp. 77-88 ◽  
Author(s):  
Kristen E. Funk ◽  
Stefani N. Thomas ◽  
Kelsey N. Schafer ◽  
Grace L. Cooper ◽  
Zhongping Liao ◽  
...  
Keyword(s):  
Human Brain ◽  
Tau Protein ◽  
Protein Function ◽  
Lysine Methylation ◽  
Post Translational Modification ◽  
Post Translational Modifications ◽  
Aggregation Propensity ◽  
Normal Human ◽  
Tau Aggregation

Diverse post-translational modifications regulate tau protein function and misfolding. In the present study we identified lysine methylation as a tau post-translational modification in normal human brain, and found it depressed tau aggregation propensity when modelled in vitro.

scholarly journals S-Nitrosylation of RhoGAP Myosin9A Is Altered in Advanced Diabetic Kidney Disease

2021 ◽  
Vol 8 ◽  
Author(s):  
Qi Li ◽  
Delma Veron ◽  
Alda Tufro
Keyword(s):  
Kidney Disease ◽  
High Glucose ◽  
Diabetic Kidney Disease ◽  
Diabetic Mice ◽  
Post Translational Modification ◽  
No Donor ◽  
Diabetic Kidney ◽  
Rhoa Activity

The molecular pathogenesis of diabetic kidney disease progression is complex and remains unresolved. Rho-GAP MYO9A was recently identified as a novel podocyte protein and a candidate gene for monogenic FSGS. Myo9A involvement in diabetic kidney disease has been suggested. Here, we examined the effect of diabetic milieu on Myo9A expression in vivo and in vitro. We determined that Myo9A undergoes S-nitrosylation, a post-translational modification dependent on nitric oxide (NO) availability. Diabetic mice with nodular glomerulosclerosis and severe proteinuria associated with doxycycline-induced, podocyte-specific VEGF164 gain-of-function showed markedly decreased glomerular Myo9A expression and S-nitrosylation, as compared to uninduced diabetic mice. Immortalized mouse podocytes exposed to high glucose revealed decreased Myo9A expression, assessed by qPCR, immunoblot and immunocytochemistry, and reduced Myo9A S-nitrosylation (SNO-Myo9A), assessed by proximity link assay and biotin switch test, functionally resulting in abnormal podocyte migration. These defects were abrogated by exposure to a NO donor and were not due to hyperosmolarity. Our data demonstrate that high-glucose induced decrease of both Myo9A expression and SNO-Myo9A is regulated by NO availability. We detected S-nitrosylation of Myo9A interacting proteins RhoA and actin, which was also altered by high glucose and NO dependent. RhoA activity inversely related to SNO-RhoA. Collectively, data suggest that dysregulation of SNO-Myo9A, SNO-RhoA and SNO-actin may contribute to the pathogenesis of advanced diabetic kidney disease and may be amenable to therapeutic targeting.

scholarly journals Recent advances in the regulation of plant immunity by S-nitrosylation

2020 ◽  
Author(s):  
Jibril Lubega ◽  
Saima Umbreen ◽  
Gary J Loake
Keyword(s):  
Plant Immunity ◽  
Protein S ◽  
Cellular Protein ◽  
Effector Proteins ◽  
Host Cells ◽  
Immune Functions ◽  
Post Translational Modification ◽  
No Donor ◽  
Reactive Protein ◽  
Recent Advances

Abstract S-nitrosylation, the addition of a nitric oxide (NO) moiety to a reactive protein cysteine (Cys) thiol, to form a protein S-nitrosothiol (SNO), is emerging as a key regulatory post-translational modification (PTM) to control the plant immune response. NO also S-nitrosylates the antioxidant tripeptide, glutathione, to form S-nitrosoglutathione (GSNO), both a storage reservoir of NO bioactivity and a natural NO donor. GSNO and, by extension, S-nitrosylation, are controlled by GSNO reductase1 (GSNOR1). The emerging data suggest that GSNOR1 itself is a target of NO-mediated S-nitrosylation, which subsequently controls its selective autophagy, regulating cellular protein SNO levels. Recent findings also suggest that S-nitrosylation may be deployed by pathogen-challenged host cells to counteract the effect of delivered microbial effector proteins that promote pathogenesis and by the pathogens themselves to augment virulence. Significantly, it also appears that S-nitrosylation may regulate plant immune functions by controlling SUMOylation, a peptide-based PTM. In this context, global SUMOylation is regulated by S-nitrosylation of SUMO conjugating enzyme 1 (SCE1) at Cys139. This redox-based PTM has also been shown to control the function of a key zinc finger transcriptional regulator during the establishment of plant immunity. Here, we provide an update of these recent advances.

Glutaredoxin AtGRXC2 catalyses inhibitory glutathionylation of Arabidopsis BRI1-associated receptor-like kinase 1 (BAK1) in vitro

2015 ◽  
Vol 467 (3) ◽  
pp. 399-413 ◽  
Author(s):  
Kyle W. Bender ◽  
Xuejun Wang ◽  
George B. Cheng ◽  
Hyoung Seok Kim ◽  
Raymond E. Zielinski ◽  
...  
Keyword(s):  
Protein Kinases ◽  
Redox Regulation ◽  
Kinase Activity ◽  
Cytoplasmic Domain ◽  
Post Translational Modification ◽  
Cysteine Oxidation ◽  
Receptor Like Kinase ◽  
Reversible Protein Phosphorylation ◽  
Two Hybrid

Reversible protein phosphorylation, catalysed by protein kinases, is the most widely studied post-translational modification (PTM), whereas the analysis of other modifications such as S-thiolation is in its relative infancy. In a yeast-two-hybrid (Y2H) screen, we identified a number of novel putative brassinosteroid insensitive 1 (BR1)-associated receptor-like kinase 1 (BAK1) interacting proteins including several proteins related to redox regulation. Glutaredoxin (GRX) C2 (AtGRXC2) was among candidate proteins identified in the Y2H screen and its interaction with recombinant Flag–BAK1 cytoplasmic domain was confirmed using an in vitro pull-down approach. We show that BAK1 peptide kinase activity is sensitive to the oxidizing agents H2O2 and diamide in vitro, suggesting that cysteine oxidation might contribute to control of BAK1 activity. Furthermore, BAK1 was glutathionylated and this reaction could occur via a thiolate-dependent reaction with GSSG or a H2O2-dependent reaction with GSH and inhibited kinase activity. Surprisingly, both reactions were catalysed by AtGRXC2 at lower concentrations of GSSG or GSH than reacted non-enzymatically. Using MALDI–TOF MS, we identified Cys353, Cys374 and Cys408 as potential sites of glutathionylation on the BAK1 cytoplasmic domain and directed mutagenesis suggests that Cys353 and Cys408 are major sites of GRXC2-mediated glutathionylation. Collectively, these results highlight the potential for redox control of BAK1 and demonstrate the ability of AtGRXC2 to catalyse protein glutathionylation, a function not previously described for any plant GRX. The present work presents a foundation for future studies of glutathionylation of plant receptor-like protein kinases (RLKs) as well as for the analysis of activities of plant GRXs.

scholarly journals Redox Regulation by Protein S-Glutathionylation: From Molecular Mechanisms to Implications in Health and Disease

2020 ◽  
Vol 21 (21) ◽  
pp. 8113 ◽  
Author(s):  
Aysenur Musaogullari ◽  
Yuh-Cherng Chai
Keyword(s):  
Protein Function ◽  
Liver Diseases ◽  
Redox Regulation ◽  
Molecular Mechanisms ◽  
Protein S ◽  
Protective Mechanism ◽  
Post Translational Modification ◽  
Physiological Processes ◽  
Health And Disease ◽  
Mixed Disulfides

S-glutathionylation, the post-translational modification forming mixed disulfides between protein reactive thiols and glutathione, regulates redox-based signaling events in the cell and serves as a protective mechanism against oxidative damage. S-glutathionylation alters protein function, interactions, and localization across physiological processes, and its aberrant function is implicated in various human diseases. In this review, we discuss the current understanding of the molecular mechanisms of S-glutathionylation and describe the changing levels of expression of S-glutathionylation in the context of aging, cancer, cardiovascular, and liver diseases.

scholarly journals Protein S-nitrosation differentially modulates tomato responses to infection by hemi-biotrophic oomycetes of Phytophthora spp.

2021 ◽  
Vol 8 (1) ◽  
Author(s):  
Tereza Jedelská ◽  
Michaela Sedlářová ◽  
Jan Lochman ◽  
Lucie Činčalová ◽  
Lenka Luhová ◽  
...  
Keyword(s):  
Stress Responses ◽  
Protein Level ◽  
Protein Function ◽  
Molecular Mechanisms ◽  
Reductase Activity ◽  
Protein S ◽  
Post Inoculation ◽  
Vascular Bundles ◽  
Post Translational Modification ◽  
Defence Proteins

AbstractRegulation of protein function by reversible S-nitrosation, a post-translational modification based on the attachment of nitroso group to cysteine thiols, has emerged among key mechanisms of NO signalling in plant development and stress responses. S-nitrosoglutathione is regarded as the most abundant low-molecular-weight S-nitrosothiol in plants, where its intracellular concentrations are modulated by S-nitrosoglutathione reductase. We analysed modulations of S-nitrosothiols and protein S-nitrosation mediated by S-nitrosoglutathione reductase in cultivated Solanum lycopersicum (susceptible) and wild Solanum habrochaites (resistant genotype) up to 96 h post inoculation (hpi) by two hemibiotrophic oomycetes, Phytophthora infestans and Phytophthora parasitica. S-nitrosoglutathione reductase activity and protein level were decreased by P. infestans and P. parasitica infection in both genotypes, whereas protein S-nitrosothiols were increased by P. infestans infection, particularly at 72 hpi related to pathogen biotrophy–necrotrophy transition. Increased levels of S-nitrosothiols localised in both proximal and distal parts to the infection site, which suggests together with their localisation to vascular bundles a signalling role in systemic responses. S-nitrosation targets in plants infected with P. infestans identified by a proteomic analysis include namely antioxidant and defence proteins, together with important proteins of metabolic, regulatory and structural functions. Ascorbate peroxidase S-nitrosation was observed in both genotypes in parallel to increased enzyme activity and protein level during P. infestans pathogenesis, namely in the susceptible genotype. These results show important regulatory functions of protein S-nitrosation in concerting molecular mechanisms of plant resistance to hemibiotrophic pathogens.

scholarly journals The phosphohistidine phosphatase SixA dephosphorylates the phosphocarrier NPr

2020 ◽  
pp. jbc.RA120.015121
Author(s):  
Jane E. Schulte ◽  
Manuela Roggiani ◽  
Hui Shi ◽  
Jun Zhu ◽  
Mark Goulian
Keyword(s):  
Protein Function ◽  
Growth Defect ◽  
Phosphoryl Transfer ◽  
Post Translational Modification ◽  
Phosphotransferase System ◽  
E Coli ◽  
System A ◽  
Mouse Intestine ◽  
Histidine Phosphorylation

Histidine phosphorylation is a post-translational modification that alters protein function and also serves as an intermediate of phosphoryl transfer. Although phosphohistidine is relatively unstable, enzymatic dephosphorylation of this residue is apparently needed in some contexts, since both prokaryotic and eukaryotic phosphohistidine phosphatases have been reported. Here we identify the mechanism by which a bacterial phosphohistidine phosphatase dephosphorylates the nitrogen-related phosphotransferase system, a broadly conserved bacterial pathway that controls diverse metabolic processes. We show that the phosphatase SixA dephosphorylates the phosphocarrier protein NPr, and that the reaction proceeds through phosphoryl transfer from a histidine on NPr to a histidine on SixA. In addition, we show that Escherichia coli lacking SixA are out-competed by wild-type E. coli in the context of commensal colonization of the mouse intestine. Notably, this colonization defect requires NPr and is distinct from a previously identified in vitro growth defect associated with dysregulation of the nitrogen-related phosphotransferase system. The wide-spread conservation of SixA, and its coincidence with the phosphotransferase system studied here, suggests that this dephosphorylation mechanism may be conserved in other bacteria.

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