Your search keyword '"H3K18 acetylation"' showing total 10 results

1. Curcumin protects against manganese-induced neurotoxicity in rat by regulating oxidative stress-related gene expression via H3K27 acetylation

Author

Yue Yang, Ying Liu, An-Liu Zhang, Shun-Fang Tang, Qian Ming, Chun-Yan Ao, Yan Liu, Chang-Zhe Li, Chun Yu, Hua Zhao, Li Chen, and Jun Li

Subjects

Curcumin, Manganese, H3K18 acetylation, H3K27 acetylation, Oxidative stress, Neurodegenerative disease, Environmental pollution, TD172-193.5, Environmental sciences, GE1-350

Abstract

Long-term manganese exposure causes a neurodegenerative disorder referred to as manganese poisoning, but the mechanism remains unclear and no specific treatment is available. Oxidative stress is widely recognised as one of the main causes of manganese-induced neurotoxicity. In recent years, the role of histone acetylation in neurodegenerative diseases has been widely concerned. curcumin is a natural polyphenol compound extracted from the rhizome of turmeric and exhibits both antioxidant and neuroprotective properties. Therefore, we aimed to investigate whether and how curcumin protects against manganese-induced neurotoxicity from the perspective of histone acetylation, based on the reversibility of histone acetylation modification. In this study, rats were treated with or without curcumin and subjected to long-term manganese exposure. Results that treatment of manganese decreased the protein expression of H3K18 acetylation and H3K27 acetylation at the promoters of oxidative stress-related genes and inhibited the expression of these genes. Nevertheless, curcumin increased the H3K27 acetylation level at the manganese superoxide dismutase (SOD2) gene promoter and promoted the expression of SOD2 gene. Oxidative damage in the rat striatum as well as learning and memory dysfunction were ameliorated after curcumin treatment. Taken together, our results suggest that the regulation of oxidative stress by histone acetylation may be a key mechanism of manganese-induced neurotoxicity. In addition, curcumin ameliorates Mn-induced neurotoxicity may be due to alleviation of oxidative damage mediated by increased activation of H3K27 acetylation at the SOD2 gene promoter.

Published

2022

2. Dynamic Histone H3 Modifications Regulate Meiosis Initiation via Respiration

Author

Jian Shi, Yanjie Ma, Hui Hua, Yujiao Liu, Wei Li, Hongxiu Yu, and Chao Liu

Subjects

histone modifications, H3K18 acetylation, meiosis initiation, RIM101, SMP1, Biology (General), QH301-705.5

Abstract

Meiosis is essential for genetic stability and diversity during sexual reproduction in most eukaryotes. Chromatin structure and gene expression are drastically changed during meiosis, and various histone modifications have been reported to participate in this unique process. However, the dynamic of histone modifications during meiosis is still not well investigated. Here, by using multiple reaction monitoring (MRM) based LC-MS/MS, we detected dynamic changes of histone H3 lysine post-translational modifications (PTMs). We firstly quantified the precise percentage of H3 modifications on different lysine sites during mouse and yeast meiosis, and found H3 acetylation and methylation were dramatically changed. To further study the potential functions of H3 acetylation and methylation in meiosis, we performed histone H3 lysine mutant screening in yeast, and found that yeast strains lacking H3K18 acetylation (H3K18ac) failed to initiate meiosis due to insufficient IME1 expression. Further studies showed that the absence of H3K18ac impaired respiration, leading to the reduction of Rim101p, which further upregulated a negative regulator of IME1 transcription, Smp1p. Together, our studies reveal a novel meiosis initiation pathway mediated by histone H3 modifications.

Published

2021

3. Anticancer drug mithramycin interacts with core histones: An additional mode of action of the DNA groove binder

Author

Amrita Banerjee, Sulagna Sanyal, Kirti K. Kulkarni, Kuladip Jana, Siddhartha Roy, Chandrima Das, and Dipak Dasgupta

Subjects

Mithramycin, Core histones, Dual binding mode, Epigenetic modulator, H3K18 acetylation, Biology (General), QH301-705.5

Abstract

Mithramycin (MTR) is a clinically approved DNA-binding antitumor antibiotic currently in Phase 2 clinical trials at National Institutes of Health for treatment of osteosarcoma. In view of the resurgence in the studies of this generic antibiotic as a human medicine, we have examined the binding properties of MTR with the integral component of chromatin – histone proteins – as a part of our broad objective to classify DNA-binding molecules in terms of their ability to bind chromosomal DNA alone (single binding mode) or both histones and chromosomal DNA (dual binding mode). The present report shows that besides DNA, MTR also binds to core histones present in chromatin and thus possesses the property of dual binding in the chromatin context. In contrast to the MTR–DNA interaction, association of MTR with histones does not require obligatory presence of bivalent metal ion like Mg2+. As a consequence of its ability to interact with core histones, MTR inhibits histone H3 acetylation at lysine 18, an important signature of active chromatin, in vitro and ex vivo. Reanalysis of microarray data of Ewing sarcoma cell lines shows that upon MTR treatment there is a significant down regulation of genes, possibly implicating a repression of H3K18Ac-enriched genes apart from DNA-binding transcription factors. Association of MTR with core histones and its ability to alter post-translational modification of histone H3 clearly indicates an additional mode of action of this anticancer drug that could be implicated in novel therapeutic strategies.

Published

2014

4. Anticancer drug mithramycin interacts with core histones: An additional mode of action of the DNA groove binder.

Author

Banerjee, Amrita, Sanyal, Sulagna, Kulkarni, Kirti K., Jana, Kuladip, Roy, Siddhartha, Das, Chandrima, and Dasgupta, Dipak

Subjects

ANTINEOPLASTIC agents, HISTONES, DNA-binding proteins, CLINICAL trials, OSTEOSARCOMA, TRANSCRIPTION factors

Abstract

Mithramycin (MTR) is a clinically approved DNA-binding antitumor antibiotic currently in Phase 2 clinical trials at National Institutes of Health for treatment of osteosarcoma. In view of the resurgence in the studies of this generic antibiotic as a human medicine, we have examined the binding properties of MTR with the integral component of chromatin – histone proteins – as a part of our broad objective to classify DNA-binding molecules in terms of their ability to bind chromosomal DNA alone (single binding mode) or both histones and chromosomal DNA (dual binding mode). The present report shows that besides DNA, MTR also binds to core histones present in chromatin and thus possesses the property of dual binding in the chromatin context. In contrast to the MTR–DNA interaction, association of MTR with histones does not require obligatory presence of bivalent metal ion like Mg 2+ . As a consequence of its ability to interact with core histones, MTR inhibits histone H3 acetylation at lysine 18, an important signature of active chromatin, in vitro and ex vivo . Reanalysis of microarray data of Ewing sarcoma cell lines shows that upon MTR treatment there is a significant down regulation of genes, possibly implicating a repression of H3K18Ac-enriched genes apart from DNA-binding transcription factors. Association of MTR with core histones and its ability to alter post-translational modification of histone H3 clearly indicates an additional mode of action of this anticancer drug that could be implicated in novel therapeutic strategies. [ABSTRACT FROM AUTHOR]

Published

2014

5. Dynamic Histone H3 Modifications Regulate Meiosis Initiation via Respiration

Author

Yujiao Liu, Jian Shi, Hongxiu Yu, Chao Liu, Hui Hua, Wei Li, and Yanjie Ma

Subjects

0301 basic medicine, Lysine, 03 medical and health sciences, Histone H3, Cell and Developmental Biology, 0302 clinical medicine, Meiosis, Transcription (biology), lcsh:QH301-705.5, Original Research, meiosis initiation, biology, Chemistry, histone modifications, RIM101, Cell Biology, Methylation, Chromatin, Cell biology, H3K18 acetylation, 030104 developmental biology, Histone, lcsh:Biology (General), Acetylation, biology.protein, SMP1, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Meiosis is essential for genetic stability and diversity during sexual reproduction in most eukaryotes. Chromatin structure and gene expression are drastically changed during meiosis, and various histone modifications have been reported to participate in this unique process. However, the dynamic of histone modifications during meiosis is still not well investigated. Here, by using multiple reaction monitoring (MRM) based LC-MS/MS, we detected dynamic changes of histone H3 lysine post-translational modifications (PTMs). We firstly quantified the precise percentage of H3 modifications on different lysine sites during mouse and yeast meiosis, and found H3 acetylation and methylation were dramatically changed. To further study the potential functions of H3 acetylation and methylation in meiosis, we performed histone H3 lysine mutant screening in yeast, and found that yeast strains lacking H3K18 acetylation (H3K18ac) failed to initiate meiosis due to insufficient IME1 expression. Further studies showed that the absence of H3K18ac impaired respiration, leading to the reduction of Rim101p, which further upregulated a negative regulator of IME1 transcription, Smp1p. Together, our studies reveal a novel meiosis initiation pathway mediated by histone H3 modifications.

Published

2020

6. Curcumin protects against manganese-induced neurotoxicity in rat by regulating oxidative stress-related gene expression via H3K27 acetylation.

Author

Yang, Yue, Liu, Ying, Zhang, An-Liu, Tang, Shun-Fang, Ming, Qian, Ao, Chun-Yan, Liu, Yan, Li, Chang-Zhe, Yu, Chun, Zhao, Hua, Chen, Li, and Li, Jun

Subjects

GENE expression, CURCUMIN, ACETYLATION, HISTONE acetylation, NEUROTOXICOLOGY, MEMORY disorders

Abstract

Long-term manganese exposure causes a neurodegenerative disorder referred to as manganese poisoning, but the mechanism remains unclear and no specific treatment is available. Oxidative stress is widely recognised as one of the main causes of manganese-induced neurotoxicity. In recent years, the role of histone acetylation in neurodegenerative diseases has been widely concerned. curcumin is a natural polyphenol compound extracted from the rhizome of turmeric and exhibits both antioxidant and neuroprotective properties. Therefore, we aimed to investigate whether and how curcumin protects against manganese-induced neurotoxicity from the perspective of histone acetylation, based on the reversibility of histone acetylation modification. In this study, rats were treated with or without curcumin and subjected to long-term manganese exposure. Results that treatment of manganese decreased the protein expression of H3K18 acetylation and H3K27 acetylation at the promoters of oxidative stress-related genes and inhibited the expression of these genes. Nevertheless, curcumin increased the H3K27 acetylation level at the manganese superoxide dismutase (SOD2) gene promoter and promoted the expression of SOD2 gene. Oxidative damage in the rat striatum as well as learning and memory dysfunction were ameliorated after curcumin treatment. Taken together, our results suggest that the regulation of oxidative stress by histone acetylation may be a key mechanism of manganese-induced neurotoxicity. In addition, curcumin ameliorates Mn-induced neurotoxicity may be due to alleviation of oxidative damage mediated by increased activation of H3K27 acetylation at the SOD2 gene promoter. [Display omitted] • Down-acetylation levels of H3K27 and H3K18 may inhibit the expression of OSR genes. • Curcumin ameliorates Mn-induced neurotoxicity in rat. • Curcumin increases the expression of SOD2 gene by the up-acetylation level of H3K27. [ABSTRACT FROM AUTHOR]

Published

2022

7. The adenovirus E1A oncoprotein N-terminal transcriptional repression domain enhances p300 autoacetylation and inhibits histone H3 Lys18 acetylation

Author

Paul M. Loewenstein, Ling-Jun Zhao, and Maurice Green

Subjects

Cancer Research, TATA box, p300, Promoter, Biology, Molecular biology, autoacetylation, Cell biology, Chromatin, E1A 1-80, H3K18 acetylation, Histone H3, Acetylation, Transcription (biology), Cancer cell, Genetics, Transcription factor II D, reconstituted chromatin, Research Paper

Abstract

Expression of the adenovirus E1A N-terminal transcription repression domain alone (E1A 1-80) represses transcription from specific promoters such as HER2 [1] and from reconstituted chromatin [2]. Significantly, E1A 1-80 can induce the death of human breast cancer cells over-expressing the HER2 oncogene [1] as well as other cancer cells. Here, we report that E1A 1-80 alone is sufficient to inhibit H3K18 acetylation in vivo and p300-mediated H3K18 acetylation in reconstituted chromatin. Of interest, hypoacetylation of H3K18 has been correlated with the survival of tumor cells and the poor prognosis of many cancers [3, 4]. E1A 1-80 enhances p300 autoacetylation and concurrently inhibits H3K18 acetylation in chromatin in a dose-dependent manner. Pre-acetylation of p300 by incubation with acetyl-CoA alone reduces p300's ability to acetylate H3K18 in chromatin. Additional acetylation of p300 in the presence of E1A 1-80 produces stronger inhibition of H3K18 acetylation. These findings indicate that autoacetylation of p300 greatly reduces its ability to acetylate H3K18. The results reported here combined with our previous findings suggest that E1A can repress transcription by multiple strategies, including altering the chromatin modifying activity of p300 and dissociating TFIID from the TATA box thus disrupting formation of the transcription pre-initiation complex [5, 6].

Published

2015

8. Dynamic Histone H3 Modifications Regulate Meiosis Initiation via Respiration.

Author

Shi J, Ma Y, Hua H, Liu Y, Li W, Yu H, and Liu C

Abstract

Meiosis is essential for genetic stability and diversity during sexual reproduction in most eukaryotes. Chromatin structure and gene expression are drastically changed during meiosis, and various histone modifications have been reported to participate in this unique process. However, the dynamic of histone modifications during meiosis is still not well investigated. Here, by using multiple reaction monitoring (MRM) based LC-MS/MS, we detected dynamic changes of histone H3 lysine post-translational modifications (PTMs). We firstly quantified the precise percentage of H3 modifications on different lysine sites during mouse and yeast meiosis, and found H3 acetylation and methylation were dramatically changed. To further study the potential functions of H3 acetylation and methylation in meiosis, we performed histone H3 lysine mutant screening in yeast, and found that yeast strains lacking H3K18 acetylation (H3K18ac) failed to initiate meiosis due to insufficient IME1 expression. Further studies showed that the absence of H3K18ac impaired respiration, leading to the reduction of Rim101p, which further upregulated a negative regulator of IME1 transcription, Smp1p. Together, our studies reveal a novel meiosis initiation pathway mediated by histone H3 modifications., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Shi, Ma, Hua, Liu, Li, Yu and Liu.)

Published

2021

9. The adenovirus E1A oncoprotein N-terminal transcriptional repression domain enhances p300 autoacetylation and inhibits histone H3 Lys18 acetylation.

Author

Zhao LJ, Loewenstein PM, and Green M

Abstract

Expression of the adenovirus E1A N-terminal transcription repression domain alone (E1A 1-80) represses transcription from specific promoters such as HER2 [1] and from reconstituted chromatin [2]. Significantly, E1A 1-80 can induce the death of human breast cancer cells over-expressing the HER2 oncogene [1] as well as other cancer cells. Here, we report that E1A 1-80 alone is sufficient to inhibit H3K18 acetylation in vivo and p300-mediated H3K18 acetylation in reconstituted chromatin. Of interest, hypoacetylation of H3K18 has been correlated with the survival of tumor cells and the poor prognosis of many cancers [3, 4]. E1A 1-80 enhances p300 autoacetylation and concurrently inhibits H3K18 acetylation in chromatin in a dose-dependent manner. Pre-acetylation of p300 by incubation with acetyl-CoA alone reduces p300's ability to acetylate H3K18 in chromatin. Additional acetylation of p300 in the presence of E1A 1-80 produces stronger inhibition of H3K18 acetylation. These findings indicate that autoacetylation of p300 greatly reduces its ability to acetylate H3K18. The results reported here combined with our previous findings suggest that E1A can repress transcription by multiple strategies, including altering the chromatin modifying activity of p300 and dissociating TFIID from the TATA box thus disrupting formation of the transcription pre-initiation complex [5, 6].

Published

2015

10. Anticancer drug mithramycin interacts with core histones: An additional mode of action of the DNA groove binder

Author

Siddhartha Roy, Chandrima Das, Kirti K. Kulkarni, Sulagna Sanyal, Amrita Banerjee, Dipak Dasgupta, and Kuladip Jana

Subjects

Histone-modifying enzymes, PTM, post-translational modification, PBS, phosphate-buffered saline, TCA, trichloroacetic acid, Article, General Biochemistry, Genetics and Molecular Biology, TBST, Tris-buffered saline Tween-20, MTT, 3-(4-5 dimethylthiazol-2-yl) 2-5diphenyl-tetrazolium bromide, Histone H3, Dual binding mode, NIH, National Institutes of Health, Mithramycin, Histone code, Histone H3 acetylation, MTR, mithramycin, CBP, CREB-binding protein, CD, circular dichroism, Transcription factor, lcsh:QH301-705.5, EM, electron microscopy, H3K18Ac, histone H3 lysine 18 acetylation, biology, ITC, isothermal titration calorimetry, SGR, sanguinarine, Histone acetyltransferase, EWS-FLI1, transcription factor with a DNA binding domain FLI1 and a transcription enhancer domain EWS, FACS, fluorescence activated cell sorting, Core histones, Epigenetic modulator, HD, Huntington’s disease, Chromatin, H3K18 acetylation, Histone, Biochemistry, lcsh:Biology (General), biology.protein, HAT, histone acetyltransferase, BAC, benzalkonium chloride, BSA, bovine serum albumin, M2+, bivalent metal ion such as Mg2+

Abstract

Highlights • Mithramycin (MTR) binds to core histones but not to linker histone H1. • Unlike MTR–DNA interaction, MTR–histone association is metal independent. • MTR alters H3K18 acetylation in vitro and ex vivo. • MTR is a dual binder (binds to both DNA and histones) in the chromatin context., Mithramycin (MTR) is a clinically approved DNA-binding antitumor antibiotic currently in Phase 2 clinical trials at National Institutes of Health for treatment of osteosarcoma. In view of the resurgence in the studies of this generic antibiotic as a human medicine, we have examined the binding properties of MTR with the integral component of chromatin – histone proteins – as a part of our broad objective to classify DNA-binding molecules in terms of their ability to bind chromosomal DNA alone (single binding mode) or both histones and chromosomal DNA (dual binding mode). The present report shows that besides DNA, MTR also binds to core histones present in chromatin and thus possesses the property of dual binding in the chromatin context. In contrast to the MTR–DNA interaction, association of MTR with histones does not require obligatory presence of bivalent metal ion like Mg2+. As a consequence of its ability to interact with core histones, MTR inhibits histone H3 acetylation at lysine 18, an important signature of active chromatin, in vitro and ex vivo. Reanalysis of microarray data of Ewing sarcoma cell lines shows that upon MTR treatment there is a significant down regulation of genes, possibly implicating a repression of H3K18Ac-enriched genes apart from DNA-binding transcription factors. Association of MTR with core histones and its ability to alter post-translational modification of histone H3 clearly indicates an additional mode of action of this anticancer drug that could be implicated in novel therapeutic strategies.