Your search keyword '"Divya Vasudevan"' showing total 21 results

1. Oxygen dependence of nitric oxide-mediated signaling

Author

Jason R. Hickok, Divya Vasudevan, Kate Jablonski, and Douglas D. Thomas

Subjects

Nitric oxide, Nitric oxide synthase, Oxygen, Autooxidation, sGC, p53, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Nitric oxide (·NO) is a biologically important short-lived free radical signaling molecule. Both the enzymatic synthesis and the predominant forms of cellular metabolism of ·NO are oxygen-dependent. For these reasons, changes in local oxygen concentrations can have a profound influence on steady-state ·NO concentrations. Many proteins are regulated by ·NO in a concentration-dependent manner, but their responses are elicited at different thresholds. Using soluble guanylyl cyclase (sGC) and p53 as model ·NO-sensitive proteins, we demonstrate that their concentration-dependent responses to ·NO are a function of the O2 concentration. p53 requires relatively high steady-state ·NO concentrations (>600 nM) to induce its phosphorylation (P-ser-15), whereas sGC responds to low ·NO concentrations (

Published

2013

2. Dataset S2 from Nitric Oxide Regulates Gene Expression in Cancers by Controlling Histone Posttranslational Modifications

Author

Douglas D. Thomas, Benjamin A. Garcia, Mark Maienschein-Cline, Xing-Jun Cao, Pinal Kanabar, Neil Bahroos, Lin L. Mantell, Vy Pham, Rhea C. Bovee, Jason R. Hickok, and Divya Vasudevan

Abstract

GO terms associated with upregulated genes bearing new ∙NO-induced H3K9ac peaks around promoter regions

Published

2023

3. Supplementary Materials and Methods, Supplementary Figures 1 through 4 and Supplementary Tables 1 through 4 from Nitric Oxide Regulates Gene Expression in Cancers by Controlling Histone Posttranslational Modifications

Author

Douglas D. Thomas, Benjamin A. Garcia, Mark Maienschein-Cline, Xing-Jun Cao, Pinal Kanabar, Neil Bahroos, Lin L. Mantell, Vy Pham, Rhea C. Bovee, Jason R. Hickok, and Divya Vasudevan

Abstract

Supplementary Materials and Methods. Figure S1. Nitric oxide induces significant changes in histone posttranslational modifications. Figure S2. NO-mediated gene expression changes are consistent with the induction of an oncogenic phenotype. Figure S3. Nitric oxide alters the distribution patterns of H3K9ac and H3K9me2 across the genome. Figure S4. NO-upregulated genes with a new promoter-associated H3K9ac peak are involved in critical tumorigenic pathways. Table S1. NO-mediated changes in global levels of histone acetylation. Table S2. List of NO-regulated miRNAs (1.5 Fold Change cut-off). Table S3. Control ChIP-PCR primer sequences. Table S4. List of transcription factors with binding motifs found exclusively around promoters of upregulated genes with a new NO-induced H3K9ac peak.

Published

2023

4. Media fingerprinting of cell culture media a standardized analytical test method suite and three-tier approach

Author

Gitanjali Talreja, Amandine Calvet, Cheryl Fuchs, Nadya Morales-Cumming, Mary Szorik, Divya Vasudevan, Alaric Collins, Jude Lakbub, Shawn Nelson, Keith Freel, Lesley Holt, Jannika Kremer, Louisa Mitchell, and Jane Worthington

Published

2022

5. Raw Materials strategy

Author

Veera Padmanbhan, Bijan Zakeri, Sudheer Sami, Stefan Minning, Michael DiFore, Jessica Mondia, Nathaniel Fair, Doug Berry, Chris Lyman, Laura McFadden, Veronique Deparis, Janmeet Anant, Wade Nudson, Laura Bentley, Vesna Stergar, Xiaoya Hu, Chris Wiedel, Tzu Chiang Han, Eric Shierly, Stefan Paschen, Divya Vasudevan, Elham Biouet, Sara Dorman, Fan Gao, Catherien Buchere, Benjamin Jequier, Michelle Ferreri, Nicola Coles, Lesley Holt, Jannika Kremer, and Isabelle Lequeux

Published

2022

6. Is PD-L1 a consistent biomarker for anti-PD-1 therapy? The model of balstilimab in a virally-driven tumor

Author

Manuel Hildago, Cailin E. Joyce, Joseph Elan Grossman, and Divya Vasudevan

Subjects

Cancer Research, medicine.medical_treatment, Anti pd 1, Antibodies, Monoclonal, Neoplasms therapy, Immunotherapy, Biology, Predictive markers, B7-H1 Antigen, Editorial, Neoplasms, PD-L1, Biomarkers, Tumor, Genetics, medicine, biology.protein, Cancer research, Humans, Biomarker (medicine), Immune Checkpoint Inhibitors, Molecular Biology, Tumor immunology

Published

2021

7. Nitric oxide, the new architect of epigenetic landscapes

Author

Divya Vasudevan, Rhea C. Bovee, and Douglas D. Thomas

Subjects

0301 basic medicine, Cancer Research, Epigenetic regulation of neurogenesis, Cell division, Physiology, Clinical Biochemistry, Cell, Biology, Nitric Oxide, Biochemistry, Epigenesis, Genetic, Histones, 03 medical and health sciences, microRNA, Gene expression, medicine, Animals, Humans, Epigenetics, DNA Methylation, Phenotype, Cell biology, MicroRNAs, 030104 developmental biology, medicine.anatomical_structure, DNA methylation, Protein Processing, Post-Translational, Signal Transduction

Abstract

Nitric oxide (NO) is an endogenously produced signaling molecule with multiple regulatory functions in physiology and disease. The most studied molecular mechanisms underlying the biological functions of NO include its reaction with heme proteins and regulation of protein activity via modification of thiol residues. A significant number of transcriptional responses and phenotypes observed in NO microenvironments, however, still lack mechanistic understanding. Recent studies shed new light on NO signaling by revealing its influence on epigenetic changes within the cell. Epigenetic alterations are important determinants of transcriptional responses and cell phenotypes, which can relay heritable information during cell division. As transcription across the genome is highly sensitive to these upstream epigenetic changes, this mode of NO signaling provides an alternate explanation for NO-mediated gene expression changes and phenotypes. This review will provide an overview of the interplay between NO and epigenetics as well as emphasize the unprecedented importance of these pathways to explain phenotypic effects associated with biological NO synthesis.

Published

2016

8. The Compromise of Macrophage Functions by Hyperoxia Is Attenuated by Ethacrynic Acid via Inhibition of NF-κB–Mediated Release of High-Mobility Group Box-1

Author

Lin L. Mantell, Douglas D. Thomas, Charles R. Ashby, Michelle Zur, Daniel J. Antoine, Samir Gorasiya, Mao Wang, Huan Yang, Divya Vasudevan, Lokesh Sharma, Wenjun Wu, and Ravikumar Sitapara

Subjects

Lipopolysaccharides, Pulmonary and Respiratory Medicine, Phagocytosis, Clinical Biochemistry, chemical and pharmacologic phenomena, Hyperoxia, Biology, HMGB1, Mice, chemistry.chemical_compound, Extracellular, medicine, Animals, Macrophage, HMGB1 Protein, Molecular Biology, Cells, Cultured, Original Research, Macrophages, NF-kappa B, NF-κB, Cell Biology, Cell biology, Prolonged exposure, Ethacrynic Acid, High-mobility group, chemistry, Immunology, biology.protein, medicine.symptom, Signal Transduction

Abstract

The prolonged exposure to hyperoxia can compromise macrophage functions and contribute to the development of ventilator-associated pneumonia. High levels of extracellular high-mobility group box-1 (HMGB1) in the airways of mice exposed to hyperoxia can directly cause macrophage dysfunction. Hence, inhibition of the release of nuclear HMGB1 into the extracellular milieu may help to maintain macrophage functions under hyperoxic conditions. The present study investigates whether ethacrynic acid (EA) affects hyperoxia-induced HMGB1 release from macrophages and improves their functions. Macrophage-like RAW 264.7 cells and bone marrow–derived macrophages were exposed to different concentrations of EA for 24 hours in the presence of 95% O2. EA significantly decreased the accumulation of extracellular HMGB1 in cultured media. Importantly, the phagocytic activity and migration capability of macrophages were significantly enhanced in EA-treated cells. Interestingly, hyperoxia-induced NF-κB activation was also inhibited in these cells. To determine whether NF-κB plays a role in hyperoxia-induced HMGB1 release, BAY 11-7082, an inhibitor of NF-κB activation, was used. Similar to EA, BAY 11-7082 significantly inhibited the accumulation of extracellular HMGB1 and improved hyperoxia-compromised macrophage migration and phagocytic activity. Furthermore, 24-hour hyperoxic exposure of macrophages caused hyperacetylation of HMGB1 and its subsequent cytoplasmic translocation and release, which were inhibited by EA and BAY 11-7082. Together, these results suggest that EA enhances hyperoxia-compromised macrophage functions by inhibiting HMGB1 hyperacetylation and its release from macrophages, possibly through attenuation of the NF-κB activation. Therefore, the activation of NF-κB could be one of the underlying mechanisms that mediate hyperoxia-compromised macrophage functions.

Published

2015

9. Prostate cancer-associated SPOP mutations confer resistance to BET inhibitors through stabilization of BRD4

Author

Divya Vasudevan, Liewei Wang, Wei Zhang, Francisco Beca, Shengwu Liu, Qing Zhong, Jinfang Zhang, Xiaoning Li, Jiaoti Huang, Wenjian Gan, Hiroyuki Inuzuka, Yu Chen, Shangqian Wang, Jianping Guo, Levi A. Garraway, Christopher E. Barbieri, Mark A. Rubin, Pengda Liu, Lorenz Buser, Ling Huang, Kwok-Kin Wong, Wenyi Wei, Ting Chen, Mirjam Blattner, James E. Bradner, Xiangpeng Dai, Peter J. Wild, Dennis L. Buckley, Andrew H. Beck, Senthil K. Muthuswamy, Jun Qi, and Kouhei Shimizu

Subjects

0301 basic medicine, Male, BRD4, Immunoblotting, chemical and pharmacologic phenomena, Apoptosis, Cell Cycle Proteins, SPOP, Biology, Protein Serine-Threonine Kinases, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Prostate cancer, Benzodiazepines, Prostate, medicine, Humans, Immunoprecipitation, Molecular Targeted Therapy, Cell Proliferation, HEK 293 cells, Ubiquitination, Cancer, Nuclear Proteins, Prostatic Neoplasms, RNA-Binding Proteins, hemic and immune systems, General Medicine, Azepines, Cell cycle, Triazoles, medicine.disease, Cullin Proteins, 3. Good health, Bromodomain, Thalidomide, Repressor Proteins, 030104 developmental biology, medicine.anatomical_structure, HEK293 Cells, Drug Resistance, Neoplasm, Immunology, Mutation, Cancer research, HeLa Cells, Transcription Factors

Abstract

The bromodomain and extraterminal (BET) family of proteins comprises four members-BRD2, BRD3, BRD4 and the testis-specific isoform BRDT-that largely function as transcriptional coactivators and play critical roles in various cellular processes, including the cell cycle, apoptosis, migration and invasion. BET proteins enhance the oncogenic functions of major cancer drivers by elevating the expression of these drivers, such as c-Myc in leukemia, or by promoting the transcriptional activities of oncogenic factors, such as AR and ERG in prostate cancer. Pathologically, BET proteins are frequently overexpressed and are clinically linked to various types of human cancer; they are therefore being pursued as attractive therapeutic targets for selective inhibition in patients with cancer. To this end, a number of bromodomain inhibitors, including JQ1 and I-BET, have been developed and have shown promising outcomes in early clinical trials. Although resistance to BET inhibitors has been documented in preclinical models, the molecular mechanisms underlying acquired resistance are largely unknown. Here we report that cullin-3SPOP earmarks BET proteins, including BRD2, BRD3 and BRD4, for ubiquitination-mediated degradation. Pathologically, prostate cancer-associated SPOP mutants fail to interact with and promote the degradation of BET proteins, leading to their elevated abundance in SPOP-mutant prostate cancer. As a result, prostate cancer cell lines and organoids derived from individuals harboring SPOP mutations are more resistant to BET-inhibitor-induced cell growth arrest and apoptosis. Therefore, our results elucidate the tumor-suppressor role of SPOP in prostate cancer in which it acts as a negative regulator of BET protein stability and also provide a molecular mechanism for resistance to BET inhibitors in individuals with prostate cancer bearing SPOP mutations.

Published

2017

10. Contributors

Author

Amrita Ahluwalia, Takaaki Akaike, María Noel Álvarez, Roger A. Alvarez, Debashree Basudhar, Christopher L. Bianco, Timothy R. Billiar, Rhea C. Bovee, Paul S. Brookes, Laura Castro, Robert Y.S. Cheng, Natalia Correa-Aragunde, Miriam M. Cortese-Krott, Meihong Deng, Qiang Du, Raul A. Dulce, Ulrich Förstermann, Martin Feelisch, Ingrid Fleming, Noelia Foresi, Bruce A. Freeman, Julia Fritsch, Jon M. Fukuto, David A. Geller, Mark T. Gladwin, Hartmut Grasemann, Madison Greer, Joshua M. Hare, Jason R. Hickok, Neil Hogg, Fernando Holguin, Fumito Ichinose, Daniel A. Jones, Balaraman Kalyanaraman, Gregory J. Kato, Eric E. Kelley, Malte Kelm, Christopher G. Kevil, Christopher Kevil, Daniel B. Kim-Shapiro, Doris Koesling, Christian M. Kramer, Shathiyah Kulandavelu, Yoshito Kumagai, Lorenzo Lamattina, Jack R. Lancaster, Zhao Lei, Huige Li, Stuart A. Lipton, Patricia A. Loughran, Jon O. Lundberg, Evanthia Mergia, Claudia R. Morris, Péter Nagy, Tomohiro Nakamura, Andreas Papapetropoulos, Rakesh P. Patel, Michaela Pekarova, Lucía Piacenza, Carolina Prolo, Natalia Ríos, Rafael Radi, Krishnaraj S. Rathod, Lisa A. Ridnour, Homero Rubbo, Michael Russwurm, Tomohiro Sawa, Ivonne Hernandez Schulman, Jeremy A. Scott, Sruti Shiva, Veena Somasundaram, Adam C. Straub, Csaba Szabo, Douglas D. Thomas, John P. Toscano, Andres Trostchansky, Divya Vasudevan, Eddie Weitzberg, David A. Wink, Daniel E. Winnica, Katherine C. Wood, Li Xu, Shuai Yuan, Warren M. Zapol, and Jacek Zielonka

Published

2017

11. Mechanisms of Epigenetic Regulation by Nitric Oxide

Author

Jason R. Hickok, Rhea C. Bovee, Divya Vasudevan, and Douglas D. Thomas

Subjects

0301 basic medicine, Epigenetic regulation of neurogenesis, biology, Phenotype, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Histone, Biochemistry, 030220 oncology & carcinogenesis, microRNA, Gene expression, biology.protein, Epigenetics, Soluble guanylyl cyclase, Epigenomics

Abstract

Within the human body, nitric oxide (NO) can arise from several sources including enzymatic synthesis, dietary nitrate, and pharmacological agents. Regardless of its source, the phenotypic consequences of NO production are influenced by complex microenvironmental factors that determine the target molecules NO will react with. Classical signaling mechanisms of NO are mediated via interactions with soluble guanylyl cyclase (sGC) and other heme-containing proteins or through the formation of protein adducts (S-nitrosothiols, 3-nitrotyrosine, and dinitrosyliron complexes). These interactions usually result in a loss or gain of protein function, thereby altering cellular phenotype. In addition, multiple lines of evidence have emerged recently demonstrating that a significant proportion of phenotypic changes attributed to NO production may be downstream from epigenetic regulatory events. It is becoming clear that NO affects dozens of histone modifications as well as DNA adducts, thus altering the epigenetic programs controlling the gene expression patterns that dictate cell phenotype, fate, and differentiation. This chapter will give an overview of the major NO-driven epigenetic mechanisms using specific examples.

Published

2017

12. Oxygen dependence of nitric oxide-mediated signaling

Author

Kate Jablonski, Divya Vasudevan, Jason R. Hickok, and Douglas D. Thomas

Subjects

p53, sGC, Clinical Biochemistry, DETA/NO, (Z)-1-[N-(2-aminoethyl)–N-(2-ammonioethyl)amino]diazen-1-ium-1,2-diolate, Receptors, Cytoplasmic and Nuclear, nNOS, neuronal nitric oxide synthase, NO3−, nitrate, Biochemistry, Oxygen, chemistry.chemical_compound, Mice, 0302 clinical medicine, Soluble Guanylyl Cyclase, Phosphorylation, lcsh:QH301-705.5, sGC, soluble guanylyl cyclase, 0303 health sciences, lcsh:R5-920, biology, eNOS, endothelial nitric oxide synthase, FAD, flavin adenine dinucleotide, Nitric oxide synthase, iNOS, inducible nitric oxide synthase, MCF-7 Cells, Liberation, LPS, lipopolysaccharide, Signal transduction, lcsh:Medicine (General), Research Article, Signal Transduction, P-Ser-15, phospho-serine 15, chemistry.chemical_element, ODQ, 1H-[1,2,4]Oxadiazolo[4,3–a]quinoxalin-1-one, NADPH, nicotinamide adenine dinucleotide phosphate, reduced, Nitric Oxide, Nitric oxide, Cell Line, 03 medical and health sciences, NO2−, nitrite, Animals, Humans, O2, oxygen, •NO, nitric oxide, 030304 developmental biology, Autooxidation, Sper/NO, (Z)-1-[N-[3–aminopropyl]–N-[4-(3-aminopropylammonio)butyl]-amino]diazen-1-ium-1,2-diolate, Macrophages, Organic Chemistry, BH4, tetrahydrobiopterin, Metabolism, FMN, flavin mononucleotide, chemistry, lcsh:Biology (General), Guanylate Cyclase, Km, Michaelis constant, biology.protein, cGMP, cyclic guanosine monophosphate, Tumor Suppressor Protein p53, Soluble guanylyl cyclase, 030217 neurology & neurosurgery

Abstract

Nitric oxide (•NO) is a biologically important short-lived free radical signaling molecule. Both the enzymatic synthesis and the predominant forms of cellular metabolism of •NO are oxygen-dependent. For these reasons, changes in local oxygen concentrations can have a profound influence on steady-state •NO concentrations. Many proteins are regulated by •NO in a concentration-dependent manner, but their responses are elicited at different thresholds. Using soluble guanylyl cyclase (sGC) and p53 as model •NO-sensitive proteins, we demonstrate that their concentration-dependent responses to •NO are a function of the O2 concentration. p53 requires relatively high steady-state •NO concentrations (>600 nM) to induce its phosphorylation (P-ser-15), whereas sGC responds to low •NO concentrations (, Graphical Abstract Highlights ►► O2 regulates •NO signaling by modulating •NO synthesis and metabolism. ► O2 affects •NO synthesis by regulating NOS expression and substrate availability. ► The rate of enzymatic •NO production increases linearly from 1–8% O2. ► The rate of cellular •NO metabolism increases with increasing [O2]. ► •NO-mediated sGC activation is maximal between 5% and 8% O2.

Published

2013

13. Nitric oxide regulates gene expression in cancers by controlling histone posttranslational modifications

Author

Divya Vasudevan, Benjamin A. Garcia, Lin L. Mantell, Vy Pham, Neil Bahroos, Pinal Kanabar, Xing Jun Cao, Jason R. Hickok, Mark Maienschein-Cline, Douglas D. Thomas, and Rhea C. Bovee

Subjects

Cancer Research, Epigenetic code, medicine.disease_cause, Nitric Oxide, Article, Mass Spectrometry, Epigenesis, Genetic, Histones, Cell Line, Tumor, Neoplasms, Histone H2A, medicine, Humans, Epigenetics, Cancer epigenetics, Oligonucleotide Array Sequence Analysis, biology, Molecular biology, Cell biology, Gene Expression Regulation, Neoplastic, Histone, Oncology, Histone methyltransferase, biology.protein, Histone Demethylases, Carcinogenesis, Protein Processing, Post-Translational

Abstract

Altered nitric oxide (•NO) metabolism underlies cancer pathology, but mechanisms explaining many •NO-associated phenotypes remain unclear. We have found that cellular exposure to •NO changes histone posttranslational modifications (PTM) by directly inhibiting the catalytic activity of JmjC-domain containing histone demethylases. Herein, we describe how •NO exposure links modulation of histone PTMs to gene expression changes that promote oncogenesis. Through high-resolution mass spectrometry, we generated an extensive map of •NO-mediated histone PTM changes at 15 critical lysine residues on the core histones H3 and H4. Concomitant microarray analysis demonstrated that exposure to physiologic •NO resulted in the differential expression of over 6,500 genes in breast cancer cells. Measurements of the association of H3K9me2 and H3K9ac across genomic loci revealed that differential distribution of these particular PTMs correlated with changes in the level of expression of numerous oncogenes, consistent with epigenetic code. Our results establish that •NO functions as an epigenetic regulator of gene expression mediated by changes in histone PTMs. Cancer Res; 75(24); 5299–308. ©2015 AACR.

Published

2015

14. Insights into the diverse effects of nitric oxide on tumor biology

Author

Divya, Vasudevan and Douglas D, Thomas

Subjects

Gene Expression Regulation, Neoplastic, Oxygen, Neoplasms, Humans, Nitric Oxide Synthase, Nitric Oxide, Gene Expression Regulation, Enzymologic

Abstract

Among its many roles in cellular biology, nitric oxide (·NO) has long been associated with cancers both as a protumorigenic and as an antitumorigenic agent. The dual nature of this signaling molecule in varied settings is attributable to its temporal and concentration-dependent effects that produce different phenotypes. The steady-state ·NO concentration within the cell is a balance between its rate of enzymatic synthesis from the three nitric oxide synthase (NOS) isoforms and consumption via numerous metabolic pathways and demonstrates strong dependence on the tissue oxygen concentration. NOS expression and ·NO production are often deregulated and associated with numerous types of cancers with dissimilar prognostic outcomes. ·NO influences several facets of tumor initiation and progression including DNA damage, chronic inflammation, angiogenesis, epithelial-mesenchymal transition, and metastasis, to name a few. The role of ·NO as an epigenetic modulator has also recently emerged and has potentially important mechanistic implications in regulating transcription of oncogenes and tumor-suppressor genes. ·NO-derived cellular adducts such as dinitrosyliron complexes and the formation of higher nitrogen oxides further alter its cellular behavior. Among anticancer strategies, the use of NOS as a prognostic biomarker and modulation of ·NO production for therapeutic benefit have gained importance over the past decade. Numerous ·NO-releasing drugs and NOS inhibitors have been evaluated in preclinical and clinical settings to arrest tumor growth. Taken together, ·NO affects various arms of cancer signaling networks. An overview of this complex interplay is provided in this chapter.

Published

2014

15. Upgrading dilute ethanol from syngas fermentation to n-caproate with reactor microbiomes

Author

Hanno Richter, Largus T. Angenent, and Divya Vasudevan

Subjects

Environmental Engineering, Carboxylic Acids, Biomass, Bioengineering, Waste Disposal, Fluid, chemistry.chemical_compound, Acetic acid, Bioreactors, Organic chemistry, Carboxylate, Waste Management and Disposal, Caproates, Ethanol, Renewable Energy, Sustainability and the Environment, Chemistry, Microbiota, General Medicine, Hydrogen-Ion Concentration, Biorefinery, Pulp and paper industry, Syngas fermentation, Fermentation, Gases, Methane, Syngas

Abstract

Fermentation of syngas from renewable biomass, which is part of the syngas platform, is gaining momentum. Here, the objective was to evaluate a proof-of-concept bioprocessing system with diluted ethanol and acetic acid in actual syngas fermentation effluent as the substrate for chain elongation into the product n-caproic acid, which can be separated with less energy input than ethanol. Chain elongation is performed with open cultures of microbial populations (reactor microbiomes) as part of the carboxylate platform. The highest concentration of n-caproic acid of ∼1 g L−1 was produced at a pH of 5.44 and a production rate of 1.7 g L−1 day−1. A higher n-butyrate production rate of 20 g L−1 day−1 indicated that product toxicity was limiting the chain elongation step from n-butyric acid to n-caproic acid. This result shows that the syngas and carboxylate platforms can be integrated within a biorefinery, but that product separation is necessary.

Published

2013

16. Nitric oxide modifies global histone methylation by inhibiting Jumonji C domain-containing demethylases

Author

Jason R. Hickok, Douglas D. Thomas, Divya Vasudevan, and William E. Antholine

Subjects

Jumonji Domain-Containing Histone Demethylases, Iron, Coenzymes, Down-Regulation, Nitric Oxide, Biochemistry, Methylation, Gene Expression Regulation, Enzymologic, Epigenesis, Genetic, Histones, Jurkat Cells, Mice, Histone demethylation, Histocompatibility Antigens, Histone methylation, Histone H2A, Animals, Humans, Molecular Biology, Epigenomics, biology, EZH2, Histone-Lysine N-Methyltransferase, Cell Biology, Histone methyltransferase, biology.protein, Demethylase, Histone Demethylases

Abstract

Methylation of lysine residues on histone tails is an important epigenetic modification that is dynamically regulated through the combined effects of methyltransferases and demethylases. The Jumonji C domain Fe(II) α-ketoglutarate family of proteins performs the majority of histone demethylation. We demonstrate that nitric oxide ((•)NO) directly inhibits the activity of the demethylase KDM3A by forming a nitrosyliron complex in the catalytic pocket. Exposing cells to either chemical or cellular sources of (•)NO resulted in a significant increase in dimethyl Lys-9 on histone 3 (H3K9me2), the preferred substrate for KDM3A. G9a, the primary methyltransferase acting on H3K9me2, was down-regulated in response to (•)NO, and changes in methylation state could not be accounted for by methylation in general. Furthermore, cellular iron sequestration via dinitrosyliron complex formation correlated with increased methylation. The mRNA of several histone demethylases and methyltransferases was also differentially regulated in response to (•)NO. Taken together, these data reveal three novel and distinct mechanisms whereby (•)NO can affect histone methylation as follows: direct inhibition of Jumonji C demethylase activity, reduction in iron cofactor availability, and regulation of expression of methyl-modifying enzymes. This model of (•)NO as an epigenetic modulator provides a novel explanation for nonclassical gene regulation by (•)NO.

Published

2013

17. Is S-nitrosocysteine a true surrogate for nitric oxide?

Author

Jason R. Hickok, Douglas D. Thomas, Divya Vasudevan, and Gregory R. J. Thatcher

Subjects

Biological signaling, S-Nitrosothiols, Physiology, Nitrosation, Clinical Biochemistry, Nitrosylation, Forum News & Views, Cell Biology, Nitric Oxide, Biochemistry, Redox, Nitric oxide, No donors, chemistry.chemical_compound, Mice, chemistry, S-nitrosocysteine, General Earth and Planetary Sciences, Animals, Cysteine, Molecular Biology, Intracellular, General Environmental Science

Abstract

S-Nitrosothiol (RSNO) formation is one manner by which nitric oxide (•NO) exerts its biological effects. There are several proposed mechanisms of formation of RSNO in vivo: auto-oxidation of •NO, transnitrosation, oxidative nitrosylation, and from dinitrosyliron complexes (DNIC). Both free •NO, generated by •NO donors, and S-nitrosocysteine (CysNO) are widely used to study •NO biology and signaling, including protein S-nitrosation. It is assumed that the cellular effects of both compounds are analogous and indicative of in vivo •NO biology. A quantitative comparison was made of formation of DNIC and RSNO, the major •NO-derived cellular products. In RAW 264.7 cells, both •NO and CysNO were metabolized, leading to rapid intracellular RSNO and DNIC formation. DNIC were the dominant products formed from physiologic •NO concentrations, however, and RSNO were the major product from CysNO treatment. Chelatable iron was necessary for DNIC assembly from either •NO or CysNO, but not for RSNO formation. These profound differences in RSNO and DNIC formation from •NO and CysNO question the use of CysNO as a surrogate for physiologic •NO. Researchers designing experiments intended to elucidate the biological signaling mechanisms of •NO should be aware of these differences and should consider the biological relevance of the use of exogenous CysNO. Antioxid. Redox Signal. 17, 962–968.

Published

2012

18. Histone methylation is regulated by nitric oxide

Author

Divya Vasudevan, Jason R. Hickok, and Douglas D. Thomas

Subjects

chemistry.chemical_compound, chemistry, Physiology (medical), Histone methyltransferase, EZH2, Histone methylation, Biochemistry, Nitric oxide, Cell biology

Published

2012

19. Nitric oxide regulates gene expression by altering posttranslational histone modifications: a paradigm shift in NO signaling

Author

Divya Vasudevan and Douglas D. Thomas

Subjects

Cancer Research, biology, Physiology, Clinical Biochemistry, Biochemistry, Nitric oxide, Cell biology, chemistry.chemical_compound, Histone, chemistry, Gene expression, biology.protein, No signaling

Published

2014

20. Nitric Oxide Modifies Histone Methylation Patterns by Inhibiting Jumonji C Domain Containing Demethylases

Author

Divya Vasudevan, Douglas D. Thomas, and Jason R. Hickok

Subjects

chemistry.chemical_compound, Chemistry, Physiology (medical), Histone methylation, Biochemistry, Domain (software engineering), Cell biology, Nitric oxide

Published

2012

21. Contrasting Mechanisms of Cellular S-Nitrosothiol Formation From •NO and CysNO: the Role of Chelatable Iron

Author

Jason R. Hickok, Divya Vasudevan, and Douglas D. Thomas

Subjects

Chemistry, Physiology (medical), Biophysics, Biochemistry, S-Nitrosothiols

Published

2011