Literature DB >> 32194360

A recent overview on sulforaphane as a dietary epigenetic modulator.

Abstract

Entities: CellLine Chemical Disease Gene Species

Year: 2020 PMID： 32194360 PMCID： PMC7068201 DOI： 10.17179/excli2019-2039

Source DB: PubMed Journal: EXCLI J ISSN： 1611-2156 Impact factor: 4.068

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Gene expression is mediated by chromatin epigenetic changes, including DNA methylation, histone modifications, promoter-enhancer interactions, and non-coding RNA (microRNA and long non-coding RNA)-mediated regulation (Chen et al., 2017[5]). Approximately 50 % of all tumor suppressor genes are inactivated through epigenetic modifications, rather than by genetic mechanisms, in sporadic cancers (Meeran et al., 2010[12]; Su et al., 2018[16]). Accumulating evidence suggests that epigenetic modulators are important tools to improve the efficacy of disease prevention strategies (Ratovitski, 2017[14]; Carlos-Reyes et al., 2019[4]; Hassan et al., 2019[8]). Sulforaphane ([1-isothioyanato-4-(methyl-sulfinyl)butane], SFN) is a naturally occurring, sulfur-containing isothiocyanate derivative that is found in the seeds and sprouts of cruciferous vegetables such as broccoli, cabbage, cauliflower, and kale (Vanduchova et al., 2019[19]). Because SFN induces the nuclear factor erythroid 2-related factor 2 (Nrf2)-antioxidant response element pathway that induces the cellular defense against oxidative stress (Trio et al., 2016[18]), SFN has received increased attention because it acts as an antioxidant, antimicrobial, anti-inflammatory, and anticancer agent (Vanduchova et al., 2019[19]). Various mechanisms, including apoptosis activation, nuclear factor-κB pathway inhibition, and cell cycle arrest induction, have been proposed to explain the beneficial effects of SFN in preventing multiple types of cancer (Tortorella et al., 2015[17]). Indeed, the increasing attention of SFN as an epigenetic modulator continues to contribute to new developments in clinical trials. This letter presents a summary of key recent studies investigating the function of SFN as an epigenetic modulator in several human diseases (Table 1(Tab. 1); References in Table 1: Abbas et al., 2016[1]; Ali Khan et al., 2015[2]; Cao et al., 2018[3]; Fisher et al., 2016[6]; Gao et al., 2018[7]; Lewinska et al., 2017[9]; Li et al., 2019[10]; Lubecka-Pietruszewska et al., 2015[11]; Okonkwo et al., 2018[13]; Royston et al., 2018[15]; Yang et al., 2015[20]; Yuan et al., 2018[21]; Zhao et al., 2018[22]; Zhou et al., 2019[23]). I believe that this letter will stimulate future research on the development of SFN as an epigenetic modulator for successful chemo-prevention and alternative therapeutic approaches.

Table 1

Recent updates on sulforaphane (SFN) as a dietary epigenetic modulator

Conflict of interest

The author declares no conflict of interest.

23 in total

Review 1. Dietary Sulforaphane in Cancer Chemoprevention: The Role of Epigenetic Regulation and HDAC Inhibition.

Authors: Stephanie M Tortorella; Simon G Royce; Paul V Licciardi; Tom C Karagiannis
Journal: Antioxid Redox Signal Date: 2014-12-19 Impact factor: 8.401

2. Sulforaphane protects against ethanol-induced apoptosis in neural crest cells through restoring epithelial-mesenchymal transition by epigenetically modulating the expression of Snail1.

Authors: Yihong Li; Fuqiang Yuan; Ting Wu; Lanhai Lu; Jie Liu; Wenke Feng; Shao-Yu Chen
Journal: Biochim Biophys Acta Mol Basis Dis Date: 2019-07-08 Impact factor: 5.187

3. Withaferin A and sulforaphane regulate breast cancer cell cycle progression through epigenetic mechanisms.

Authors: Kendra J Royston; Bidisha Paul; Susan Nozell; Rajani Rajbhandari; Trygve O Tollefsbol
Journal: Exp Cell Res Date: 2018-04-22 Impact factor: 3.905

4. Sulforaphane Alone and in Combination with Clofarabine Epigenetically Regulates the Expression of DNA Methylation-Silenced Tumour Suppressor Genes in Human Breast Cancer Cells.

Authors: Katarzyna Lubecka-Pietruszewska; Agnieszka Kaufman-Szymczyk; Barbara Stefanska; Barbara Cebula-Obrzut; Piotr Smolewski; Krystyna Fabianowska-Majewska
Journal: J Nutrigenet Nutrigenomics Date: 2015

5. Sulforaphane restores acetyl-histone H3 binding to Bcl-2 promoter and prevents apoptosis in ethanol-exposed neural crest cells and mouse embryos.

Authors: Fuqiang Yuan; Xiaopan Chen; Jie Liu; Wenke Feng; Lu Cai; Xiaoyang Wu; Shao-Yu Chen
Journal: Exp Neurol Date: 2017-10-22 Impact factor: 5.330

6. HDAC5-LSD1 axis regulates antineoplastic effect of natural HDAC inhibitor sulforaphane in human breast cancer cells.

Authors: Chunyu Cao; Hao Wu; Shauna N Vasilatos; Uma Chandran; Ye Qin; Yong Wan; Steffi Oesterreich; Nancy E Davidson; Yi Huang
Journal: Int J Cancer Date: 2018-04-20 Impact factor: 7.396

7. Epigenetic targets of bioactive dietary components for cancer prevention and therapy.

Authors: Syed M Meeran; Amiya Ahmed; Trygve O Tollefsbol
Journal: Clin Epigenetics Date: 2010-12-01 Impact factor: 6.551

8. Sulforaphane Reverses the Expression of Various Tumor Suppressor Genes by Targeting DNMT3B and HDAC1 in Human Cervical Cancer Cells.

Authors: Munawwar Ali Khan; Madhumitha Kedhari Sundaram; Amina Hamza; Uzma Quraishi; Dian Gunasekera; Laveena Ramesh; Payal Goala; Usama Al Alami; Mohammad Zeeshan Ansari; Tahir A Rizvi; Chhavi Sharma; Arif Hussain
Journal: Evid Based Complement Alternat Med Date: 2015-06-16 Impact factor: 2.629

9. Upregulation of miR-328 and inhibition of CREB-DNA-binding activity are critical for resveratrol-mediated suppression of matrix metalloproteinase-2 and subsequent metastatic ability in human osteosarcomas.

Authors: Shun-Fa Yang; Wei-Jiunn Lee; Peng Tan; Chih-Hsin Tang; Michael Hsiao; Feng-Koo Hsieh; Ming-Hsien Chien
Journal: Oncotarget Date: 2015-02-20

10. DNA Microarray Highlights Nrf2-Mediated Neuron Protection Targeted by Wasabi-Derived Isothiocyanates in IMR-32 Cells.

Authors: Phoebe Zapanta Trio; Satoru Fujisaki; Shunsuke Tanigawa; Ayami Hisanaga; Kozue Sakao; De-Xing Hou
Journal: Gene Regul Syst Bio Date: 2016-08-11