• Title/Summary/Keyword: Indole Glucosinolate

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Effect of Indole-3-Carbinol on Inhibition of MMP Activity via MAPK Signaling Pathway in Human Prostate Cancer Cell Line, PC3 Cells (인돌이 인체 전립선암세포 PC3 Cell 전이 관련 Matrix Metalloproteinases (MMPs) 활성과 발현에 미치는 영향)

  • Kim, Sung-Ok
    • Journal of Nutrition and Health
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    • v.41 no.3
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    • pp.224-231
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    • 2008
  • We examined the effect of indole-3-carbinol (I3C, $C_9H_9NO$), an autolysis product of a glucosinolate and a glucobrassicin in vegetables, on MMP-2, -9 activities and TIMP-l and -2 inductions via microtubule-associated protein kinase (MAPK) signaling pathway in prostate cancer cell line, PC3 cells. Our results indicated that I3C inhibited cell growth of PC3 cells in dose (0,50, 100 ,${\mu}M$) and time (0,24,48 and 72 h) dependent manners. Using gelatin zymography for MMP activity, we demonstrated that I3C significantly decrease MMP-2 and -9 activities in PC3 cells. We also observed that I3C decreased the proteins and mRNA levels of MMP-2 and -9 in PC3 cells as well. Inversely, expressions of TIMP-l and -2 protein and mRNA in PC3 cells were increased by I3C in a dose dependent manner. In another experiment, we showed that I3C inhibited PC3 cells invasiveness by using marigel invasion assay and we also found that I3C suppressed MMP transcriptional activity by MAPK signaling pathways. Taken together, our results suggest that I3C may contribute to the potential beneficial food component to prevent the cancer metastasis in prostate cancer cells. (KoreanJNutr2008; 41(3): 224~23I)

Pathogen, Insect and Weed Control Effects of Secondary Metabolites from Plants (식물유래 2차 대사물질의 병충해 및 잡초 방제효과)

  • Kim, Jong-Bum
    • Applied Biological Chemistry
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    • v.48 no.1
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    • pp.1-15
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    • 2005
  • Pathogens, insects and weeds have significantly reduced agricultural productivity. Thus, to increase the productivity, synthetic agricultural chemicals have been overused. However, these synthetic compounds that are different from natural products cannot be broken down easily in natural systems, causing the destruction of soil quality and agricultural environments and the gradually difficulty in continuous agriculture. Now agriculture is faced with the various problems of minimizing the damage in agricultural environments, securing the safety of human health, while simultaneously increasing agricultural productivity. Meanwhile, plants produce secondary metabolites to protect themselves from external invaders and to secure their region for survival. Plants infected with pathogens produce antibiotics phytoalexin; monocotyledonous plants produce flavonoids and diterpenoids phytoalexins, and dicotylodoneous plant, despite of infected pathogens, produce family-specific phytoalexin such as flavonoids in Leguminosae, indole derivatives in Cruciferae, sesquitepenoids in Solanaceae, coumarins in Umbelliferae, making the plant resistant to specific pathogen. Growth inhibitor or antifeedant substances to insects are terpenoids pyrethrin, azadirachtin, limonin, cedrelanoid, toosendanin and fraxinellone/dictamnine, and terpenoid-alkaloid mixed compounds sesquiterpene pyridine and norditerpenoids, and azepine-, amide-, loline-, stemofoline-, pyrrolizidine-alkaloids and so on. Also plants produces the substances to inhibit other plant growths to secure the regions for plant itself, which is including terpenoids essential oil and sesquiterpene lactone, and additionally, benzoxazinoids, glucosinolate, quassinoid, cyanogenic glycoside, saponin, sorgolennone, juglone and lots of other different of secondary metabolites. Hence, phytoalexin, an antibiotic compound produced by plants infected with pathogens, can be employed for pathogen control. Terpenoids and alkaloids inhibiting insect growth can be utilized for insect control. Allelochemicals, a compound released from a certain plant to hinder the growth of other plants for their survival, can be also used directly as a herbicides for weed control as well. Therefore, the use of the natural secondary metabolites for pest control might be one of the alternatives for environmentally friendly agriculture. However, the natural substances are destroyed easily causing low the pest-control efficacy, and also there is the limitation to producing the substances using plant cell. In the future, effects should be made to try to find the secondary metabolites with good pest-control effect and no harmful to human health. Also the biosynthetic pathways of secondary metabolites have to be elucidated continuously, and the metabolic engineering should be applied to improve transgenics having the resistance to specific pest.

Analysis of glucosinolates and their metabolites from napa cabbage (Brassica rapa subsp. Pekinensis) and napa cabbage kimchi using UPLC-MS/MS (UPLC-MS/MS를 이용한 배추와 배추김치의 글루코시놀레이트 및 대사체 분석)

  • Kim, Jaecheol;Park, Hyo Sun;Hwang, Keum Taek;Moon, BoKyung;Kim, Suna
    • Korean Journal of Food Science and Technology
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    • v.52 no.6
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    • pp.587-594
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    • 2020
  • In this study, we analyzed glucosinolates and their metabolites in the inner and outer parts of napa cabbage (NC; Brassica rapa subsp. pekinensis) and napa cabbage kimchi (NKC) using UPLC-ESI-MS/MS. In the extracts from NC and NKC, glucobrassicanapin (m/z 386), glucoalyssin (m/z 450), glucobrassicin (m/z 447), 4-methoxyglucobrassicin (m/z 477), and neoglucobrassicin (m/z 477) were detected using the MS scan mode ([M-H]-), and gluconapin (m/z 372→97), progoitrin (m/z 388→97), glucoiberin (m/z 422→97), 4-methoxyglucobrassicin (m/z 477→97), and neoglucobrassicin (m/z 477→447) were detected using the MS/MS MRM mode ([M-H]-). Ascorbigen (m/z 306→130) and indole-3-carboxaldehyde (I3A; m/z 146→118), which were metabolites of glucobrassicins, were detected using the MS/MS MRM ([M+H]+) mode. The peak intensities of ascorbigen in the extract from the inner and outer parts of NC were significantly higher than those of the NKC extract (p<0.05); however, there was no significant difference in I3A peak intensity between the NC and NKC extracts.

Effect of Developmental Stages on Glucosinolate Contents in Kale (Brassica oleracea var. acephala) (생장단계에 따른 케일 내 글루코시놀레이트 함량)

  • Lee, Heon-Hak;Yang, Si-Chang;Lee, Min-Ki;Ryu, Dong-Ki;Park, Suhyoung;Chung, Sun-Ok;Park, Sang Un;Lim, Yong-Pyo;Kim, Sun-Ju
    • Horticultural Science & Technology
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    • v.33 no.2
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    • pp.177-185
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    • 2015
  • The aim of this study was to investigate the amounts of glucosinolates (GSL) in kale at various development stages. Kale varieties 'Manchoo Collard' and 'TBC' were cultivated from 20 February 2012 to 3 July 2013 in the greenhouse at Chungnam National University. During the cultivation periods, samples were harvested at 35, 63, 91, 105, 119, and 133 days after sowing (DAS) and the amount of GSL quantified by HPLC. Ten types of GSL (progoitrin, sinigrin, glucoalyssin, gluconapin, glucoiberverin, 4-hydroxyglucobrassicin, glucobrassicin, 4-methoxyglucobrassicin, gluconasturtiin, and neoglucobrassicin) were observed in 'TBC', whereas nine types of GSL (the same as above, except glucoiberverin) were identified in 'Manchoo Collard'. The amount of total GSL in 'Manchoo Collard' was comparatively higher at 133 DAS (mean $8.64{\mu}mol{\cdot}g^{-1}$) and lower at 35 DAS ($1.16{\mu}mol{\cdot}g^{-1}$ dry weight, DW) of cultivation. In the case of 'TBC', the amount of GSL was higher at 91 DAS (mean $13.41{\mu}mol{\cdot}g^{-1}$) and lower at 35 DAS ($0.31{\mu}mol{\cdot}g^{-1}$ dry weight, DW). Sinigrin was the most abundant GSL (57% of total GSL) in 'Manchoo Collard' at 133 DAS and was also highest (44%) in 'TBC' at 91 DAS. Together, progoitrin, sinigrin, glucobrassicin, and gluconasturtiin, the precursor of crambene, allylisothiocyanate, indol-3-cabinol, and phenethylisothiocyanate accounted for 94 and 78% of GSL in 'Manchoo Collard' and 'TBC', respectively. Our results demonstrate that the amounts of GSL, which have potential anti-carcinogenic activity, change during development in kale.