Literature DB >> 27301252

Glucosinolate and Desulfo-glucosinolate Metabolism by a Selection of Human Gut Bacteria.

Vijitra Luang-In1,2, Abdulhadi Ali Albaser3,4, Carmen Nueno-Palop5, Mark H Bennett3, Arjan Narbad5, John T Rossiter3.   

Abstract

Glucosinolate (GSL) hydrolysis is mediated by the enzyme myrosinase which together with specifier proteins can give rise to isothiocyanates (ITCs), thiocyanates, and nitriles (NITs) in cruciferous plants. However, little is known about the metabolism of GSLs by the human gut flora. The aim of the work was to investigate the metabolic fates of sinigrin (SNG), glucotropaeolin (GTP), gluconasturtiin (GNT), and their corresponding desulfo-GSLs (DS-GSLs). Three human gut bacterial strains, Enterococcus casseliflavus CP1, Lactobacillus agilis R16, and Escherichia coli VL8, were chosen for this study. GNT was metabolized to completion within 24 h to phenethyl ITC and phenethyl NIT (PNIT) by all bacteria, except for L. agilis R16 which produced only PNIT. At least 80 % of GTP and SNG were metabolized by all bacteria within 24 h to the corresponding ITCs and NITs. The pH of media over time gradually became acidic for both L. agilis R16 and E. coli VL8, while for E. casseliflavus CP1 the media became slightly alkaline with NIT and ITC production occurring between pH 3.0 and 7.5. ITC production peaked between 4 and 10 h in most cases and gradually declined while NIT production increased and remained relatively constant over time. The total percentage products accounted for 3-53 % of the initial GSL. NITs were produced from DS-GSLs suggesting an alternative metabolism via desulfation for the food based GSLs. The metal ion dependency for NIT production for GNT and its DS form was investigated where it was shown that Fe(2+) increased NIT production, while Mg(2+) stimulated the formation of ITC.

Entities:  

Mesh:

Substances:

Year:  2016        PMID: 27301252     DOI: 10.1007/s00284-016-1079-8

Source DB:  PubMed          Journal:  Curr Microbiol        ISSN: 0343-8651            Impact factor:   2.188


  33 in total

Review 1.  Myrosinase: gene family evolution and herbivore defense in Brassicaceae.

Authors:  L Rask; E Andréasson; B Ekbom; S Eriksson; B Pontoppidan; J Meijer
Journal:  Plant Mol Biol       Date:  2000-01       Impact factor: 4.076

2.  Characterization and evolution of a myrosinase from the cabbage aphid Brevicoryne brassicae.

Authors:  A M E Jones; P Winge; A M Bones; R Cole; J T Rossiter
Journal:  Insect Biochem Mol Biol       Date:  2002-03-01       Impact factor: 4.714

3.  Comparison of the bioactivity of two glucoraphanin hydrolysis products found in broccoli, sulforaphane and sulforaphane nitrile.

Authors:  N V Matusheski; E H Jeffery
Journal:  J Agric Food Chem       Date:  2001-12       Impact factor: 5.279

4.  Sulforaphane alleviates muscular dystrophy in mdx mice by activation of Nrf2.

Authors:  Chengcao Sun; Cuili Yang; Ruilin Xue; Shujun Li; Ting Zhang; Lei Pan; Xuejiao Ma; Liang Wang; Dejia Li
Journal:  J Appl Physiol (1985)       Date:  2014-11-13

5.  Fe2+-catalyzed formation of nitriles and thionamides from intact glucosinolates.

Authors:  Natalia Bellostas; Anne D Sørensen; Jens C Sørensen; Hilmer Sørensen
Journal:  J Nat Prod       Date:  2007-12-29       Impact factor: 4.050

6.  A fast and gentle method for the isolation of myrosinase complexes from Brassicaceous seeds.

Authors:  Natalia Bellostas; Iben Lykke Petersen; Jens Christian Sørensen; Hilmer Sørensen
Journal:  J Biochem Biophys Methods       Date:  2007-11-21

7.  In vitro digestion of sinigrin and glucotropaeolin by single strains of Bifidobacterium and identification of the digestive products.

Authors:  D-L Cheng; K Hashimoto; Y Uda
Journal:  Food Chem Toxicol       Date:  2004-03       Impact factor: 6.023

8.  Lactic acid bacteria convert glucosinolates to nitriles efficiently yet differently from enterobacteriaceae.

Authors:  Jane A Mullaney; William J Kelly; Tony K McGhie; Juliet Ansell; Julian A Heyes
Journal:  J Agric Food Chem       Date:  2013-03-15       Impact factor: 5.279

9.  Sulforaphane reduces vascular inflammation in mice and prevents TNF-α-induced monocyte adhesion to primary endothelial cells through interfering with the NF-κB pathway.

Authors:  Palanisamy Nallasamy; Hongwei Si; Pon Velayutham Anandh Babu; Dengke Pan; Yu Fu; Elizabeth A S Brooke; Halley Shah; Wei Zhen; Hong Zhu; Dongmin Liu; Yunbo Li; Zhenquan Jia
Journal:  J Nutr Biochem       Date:  2014-04-04       Impact factor: 6.048

10.  Identification, synthesis, and enzymology of non-natural glucosinolate chemopreventive candidates.

Authors:  Jared R Mays; Rachel L Weller Roska; Sami Sarfaraz; Hasan Mukhtar; Scott R Rajski
Journal:  Chembiochem       Date:  2008-03-25       Impact factor: 3.164
View more
  10 in total

1.  Isolation and Characterization of Glucosinolate-Hydrolysis Enterococcus gallinarum HG001 and Escherichia coli HG002 from C57BL/6 Mouse Microbiota.

Authors:  Yao Zhang; Sisi Huang; Juan Sun; Xinjie Song; Chunmin Jiang; Yuanfeng Wu
Journal:  Indian J Microbiol       Date:  2022-02-23       Impact factor: 2.461

2.  A Metabolic Pathway for Activation of Dietary Glucosinolates by a Human Gut Symbiont.

Authors:  Catherine S Liou; Shannon J Sirk; Camil A C Diaz; Andrew P Klein; Curt R Fischer; Steven K Higginbottom; Amir Erez; Mohamed S Donia; Justin L Sonnenburg; Elizabeth S Sattely
Journal:  Cell       Date:  2020-02-20       Impact factor: 41.582

Review 3.  Is Bitterness Only a Taste? The Expanding Area of Health Benefits of Brassica Vegetables and Potential for Bitter Taste Receptors to Support Health Benefits.

Authors:  Anqi Zhao; Elizabeth H Jeffery; Michael J Miller
Journal:  Nutrients       Date:  2022-03-30       Impact factor: 5.717

4.  Dietary Broccoli Alters Rat Cecal Microbiota to Improve Glucoraphanin Hydrolysis to Bioactive Isothiocyanates.

Authors:  Xiaoji Liu; Yanling Wang; Jennifer L Hoeflinger; Bárbara P Neme; Elizabeth H Jeffery; Michael J Miller
Journal:  Nutrients       Date:  2017-03-10       Impact factor: 5.717

5.  Formation of Sulforaphane and Iberin Products from Thai Cabbage Fermented by Myrosinase-Positive Bacteria.

Authors:  Vijitra Luang-In; Sirirat Deeseenthum; Piyachat Udomwong; Worachot Saengha; Matteo Gregori
Journal:  Molecules       Date:  2018-04-19       Impact factor: 4.411

Review 6.  Gut Glucosinolate Metabolism and Isothiocyanate Production.

Authors:  Arjan Narbad; John Trevor Rossiter
Journal:  Mol Nutr Food Res       Date:  2018-07-05       Impact factor: 5.914

Review 7.  Contribution of plant food bioactives in promoting health effects of plant foods: why look at interindividual variability?

Authors:  Christine Morand; Francisco A Tomás-Barberán
Journal:  Eur J Nutr       Date:  2019-10-22       Impact factor: 5.614

8.  A new source of bacterial myrosinase isolated from endophytic Bacillus sp. NGB-B10, and its relevance in biological control activity.

Authors:  Sameh H Youseif; Hanan M K Abdel-Fatah; Mary S Khalil
Journal:  World J Microbiol Biotechnol       Date:  2022-09-03       Impact factor: 4.253

9.  The Influence of Red Cabbage Extract Nanoencapsulated with Brassica Plasma Membrane Vesicles on the Gut Microbiome of Obese Volunteers.

Authors:  Paula Garcia-Ibañez; Carles Roses; Agatha Agudelo; Fermin I Milagro; Ana M Barceló; Blanca Viadel; Juan Antonio Nieto; Diego A Moreno; Micaela Carvajal
Journal:  Foods       Date:  2021-05-10

10.  Composition of the Gut Microbiome Influences Production of Sulforaphane-Nitrile and Iberin-Nitrile from Glucosinolates in Broccoli Sprouts.

Authors:  John A Bouranis; Laura M Beaver; Jaewoo Choi; Carmen P Wong; Duo Jiang; Thomas J Sharpton; Jan F Stevens; Emily Ho
Journal:  Nutrients       Date:  2021-08-28       Impact factor: 5.717
  10 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.