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Essential Oil of Artemisia scoparia Inhibits Plant Growth by Generating Reactive Oxygen Species and Causing Oxidative Damage

We investigated the chemical composition and phytotoxicity of the essential oil extracted from leaves of Artemisia scoparia Waldst. et Kit. (red stem wormwood, Asteraceae). GC/GC-MS analyses revealed 33 chemical constituents representing 99.83% of the oil. The oil, in general, was rich in monoterpen... Full description

Journal Title: Journal of chemical ecology 2009-02-05, Vol.35 (2), p.154-162
Main Author: Singh, Harminder Pal
Other Authors: Kaur, Shalinder , Mittal, Sunil , Batish, Daizy Rani , Kohli, Ravinder Kumar
Format: Electronic Article Electronic Article
Language: English
Subjects:
Agriculture
Animal and plant ecology
Animal, plant and microbial ecology
Artemisia
Artemisia - chemistry
Article
Asteraceae
Autoecology
Biochemistry
Biological and medical sciences
Biological Microscopy
Biomedical and Life Sciences
Chemicals
Cyperus rotundus
Ecology
Electrolytes
Entomology
Fundamental and applied biological sciences. Psychology
general
Germination
Growth
Hydrogen peroxide
Life Sciences
Lipid Peroxidation
Monoterpenes - chemistry
Monoterpenes - pharmacology
Monoterpenes - toxicity
Oils, Volatile - chemistry
Oils, Volatile - pharmacology
Oils, Volatile - toxicity
Oxidative Stress - drug effects
Phalaris minor
Plant Extracts - chemistry
Plant growth
Plant Growth Regulators - chemistry
Plant Growth Regulators - pharmacology
Plant Growth Regulators - toxicity
Plant Leaves - chemistry
Plant Oils - chemistry
Plant Oils - pharmacology
Plant Oils - toxicity
Plant Roots - growth & development
Plants and fungi
Reactive Oxygen Species - metabolism
Scoparia
Weeds
Publisher: New York: Springer-Verlag
ID: ISSN: 0098-0331
Zum Text:
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recordid: cdi_gale_infotracacademiconefile_A232080883
title: Essential Oil of Artemisia scoparia Inhibits Plant Growth by Generating Reactive Oxygen Species and Causing Oxidative Damage
format: Article
creator:
  • Singh, Harminder Pal
  • Kaur, Shalinder
  • Mittal, Sunil
  • Batish, Daizy Rani
  • Kohli, Ravinder Kumar
subjects:
  • Agriculture
  • Animal and plant ecology
  • Animal, plant and microbial ecology
  • Artemisia
  • Artemisia - chemistry
  • Article
  • Asteraceae
  • Autoecology
  • Biochemistry
  • Biological and medical sciences
  • Biological Microscopy
  • Biomedical and Life Sciences
  • Chemicals
  • Cyperus rotundus
  • Ecology
  • Electrolytes
  • Entomology
  • Fundamental and applied biological sciences. Psychology
  • general
  • Germination
  • Growth
  • Hydrogen peroxide
  • Life Sciences
  • Lipid Peroxidation
  • Monoterpenes - chemistry
  • Monoterpenes - pharmacology
  • Monoterpenes - toxicity
  • Oils, Volatile - chemistry
  • Oils, Volatile - pharmacology
  • Oils, Volatile - toxicity
  • Oxidative Stress - drug effects
  • Phalaris minor
  • Plant Extracts - chemistry
  • Plant growth
  • Plant Growth Regulators - chemistry
  • Plant Growth Regulators - pharmacology
  • Plant Growth Regulators - toxicity
  • Plant Leaves - chemistry
  • Plant Oils - chemistry
  • Plant Oils - pharmacology
  • Plant Oils - toxicity
  • Plant Roots - growth & development
  • Plants and fungi
  • Reactive Oxygen Species - metabolism
  • Scoparia
  • Weeds
ispartof: Journal of chemical ecology, 2009-02-05, Vol.35 (2), p.154-162
description: We investigated the chemical composition and phytotoxicity of the essential oil extracted from leaves of Artemisia scoparia Waldst. et Kit. (red stem wormwood, Asteraceae). GC/GC-MS analyses revealed 33 chemical constituents representing 99.83% of the oil. The oil, in general, was rich in monoterpenes that constitute 71.6%, with β -myrcene (29.27%) as the major constituent followed by (+)-limonene (13.3%), ( Z )- β -ocimene (13.37%), and γ -terpinene (9.51%). The oil and β -myrcene were evaluated in a dose–response bioassay under laboratory conditions for phytotoxicity against three weeds— Avena fatua, Cyperus rotundus , and Phalaris minor . A significant reduction in germination, seedling growth, and dry matter accumulation was observed in the test weeds. At the lowest treatment of 0.07 mg/ml Artemisia oil, germination was reduced by 39%, 19%, and 10.6% in C. rotundus, P. minor , and A. fatua , respectively. However, the inhibitory effect of β -myrcene was less. In general, a dose-dependent effect was observed and the growth declined with increasing concentration. Among the three weeds, the inhibitory effect was greatest on C. rotundus , so it was selected for further studies. We explored the explanation for observed growth inhibition in terms of reactive oxygen species (ROS: lipid peroxidation, membrane integrity, and amounts of conjugated dienes and hydrogen peroxide)-induced oxidative stress. Exposure of C. rotundus to Artemisia oil or β -myrcene enhanced solute leakage, indicating membrane disintegration. There were increased levels of malondialdehyde and hydrogen peroxide, indicating lipid peroxidation and induction of oxidative stress. We conclude that Artemisia oil inhibits plant root growth through generation of ROS-induced oxidative damage.
language: eng
source:
identifier: ISSN: 0098-0331
fulltext: no_fulltext
issn:
  • 0098-0331
  • 1573-1561
url: Link


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titleEssential Oil of Artemisia scoparia Inhibits Plant Growth by Generating Reactive Oxygen Species and Causing Oxidative Damage
creatorSingh, Harminder Pal ; Kaur, Shalinder ; Mittal, Sunil ; Batish, Daizy Rani ; Kohli, Ravinder Kumar
creatorcontribSingh, Harminder Pal ; Kaur, Shalinder ; Mittal, Sunil ; Batish, Daizy Rani ; Kohli, Ravinder Kumar
descriptionWe investigated the chemical composition and phytotoxicity of the essential oil extracted from leaves of Artemisia scoparia Waldst. et Kit. (red stem wormwood, Asteraceae). GC/GC-MS analyses revealed 33 chemical constituents representing 99.83% of the oil. The oil, in general, was rich in monoterpenes that constitute 71.6%, with β -myrcene (29.27%) as the major constituent followed by (+)-limonene (13.3%), ( Z )- β -ocimene (13.37%), and γ -terpinene (9.51%). The oil and β -myrcene were evaluated in a dose–response bioassay under laboratory conditions for phytotoxicity against three weeds— Avena fatua, Cyperus rotundus , and Phalaris minor . A significant reduction in germination, seedling growth, and dry matter accumulation was observed in the test weeds. At the lowest treatment of 0.07 mg/ml Artemisia oil, germination was reduced by 39%, 19%, and 10.6% in C. rotundus, P. minor , and A. fatua , respectively. However, the inhibitory effect of β -myrcene was less. In general, a dose-dependent effect was observed and the growth declined with increasing concentration. Among the three weeds, the inhibitory effect was greatest on C. rotundus , so it was selected for further studies. We explored the explanation for observed growth inhibition in terms of reactive oxygen species (ROS: lipid peroxidation, membrane integrity, and amounts of conjugated dienes and hydrogen peroxide)-induced oxidative stress. Exposure of C. rotundus to Artemisia oil or β -myrcene enhanced solute leakage, indicating membrane disintegration. There were increased levels of malondialdehyde and hydrogen peroxide, indicating lipid peroxidation and induction of oxidative stress. We conclude that Artemisia oil inhibits plant root growth through generation of ROS-induced oxidative damage.
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languageeng
publisherNew York: Springer-Verlag
subjectAgriculture ; Animal and plant ecology ; Animal, plant and microbial ecology ; Artemisia ; Artemisia - chemistry ; Article ; Asteraceae ; Autoecology ; Biochemistry ; Biological and medical sciences ; Biological Microscopy ; Biomedical and Life Sciences ; Chemicals ; Cyperus rotundus ; Ecology ; Electrolytes ; Entomology ; Fundamental and applied biological sciences. Psychology ; general ; Germination ; Growth ; Hydrogen peroxide ; Life Sciences ; Lipid Peroxidation ; Monoterpenes - chemistry ; Monoterpenes - pharmacology ; Monoterpenes - toxicity ; Oils, Volatile - chemistry ; Oils, Volatile - pharmacology ; Oils, Volatile - toxicity ; Oxidative Stress - drug effects ; Phalaris minor ; Plant Extracts - chemistry ; Plant growth ; Plant Growth Regulators - chemistry ; Plant Growth Regulators - pharmacology ; Plant Growth Regulators - toxicity ; Plant Leaves - chemistry ; Plant Oils - chemistry ; Plant Oils - pharmacology ; Plant Oils - toxicity ; Plant Roots - growth & development ; Plants and fungi ; Reactive Oxygen Species - metabolism ; Scoparia ; Weeds
ispartofJournal of chemical ecology, 2009-02-05, Vol.35 (2), p.154-162
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descriptionWe investigated the chemical composition and phytotoxicity of the essential oil extracted from leaves of Artemisia scoparia Waldst. et Kit. (red stem wormwood, Asteraceae). GC/GC-MS analyses revealed 33 chemical constituents representing 99.83% of the oil. The oil, in general, was rich in monoterpenes that constitute 71.6%, with β -myrcene (29.27%) as the major constituent followed by (+)-limonene (13.3%), ( Z )- β -ocimene (13.37%), and γ -terpinene (9.51%). The oil and β -myrcene were evaluated in a dose–response bioassay under laboratory conditions for phytotoxicity against three weeds— Avena fatua, Cyperus rotundus , and Phalaris minor . A significant reduction in germination, seedling growth, and dry matter accumulation was observed in the test weeds. At the lowest treatment of 0.07 mg/ml Artemisia oil, germination was reduced by 39%, 19%, and 10.6% in C. rotundus, P. minor , and A. fatua , respectively. However, the inhibitory effect of β -myrcene was less. In general, a dose-dependent effect was observed and the growth declined with increasing concentration. Among the three weeds, the inhibitory effect was greatest on C. rotundus , so it was selected for further studies. We explored the explanation for observed growth inhibition in terms of reactive oxygen species (ROS: lipid peroxidation, membrane integrity, and amounts of conjugated dienes and hydrogen peroxide)-induced oxidative stress. Exposure of C. rotundus to Artemisia oil or β -myrcene enhanced solute leakage, indicating membrane disintegration. There were increased levels of malondialdehyde and hydrogen peroxide, indicating lipid peroxidation and induction of oxidative stress. We conclude that Artemisia oil inhibits plant root growth through generation of ROS-induced oxidative damage.
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31Phalaris minor
32Plant Extracts - chemistry
33Plant growth
34Plant Growth Regulators - chemistry
35Plant Growth Regulators - pharmacology
36Plant Growth Regulators - toxicity
37Plant Leaves - chemistry
38Plant Oils - chemistry
39Plant Oils - pharmacology
40Plant Oils - toxicity
41Plant Roots - growth & development
42Plants and fungi
43Reactive Oxygen Species - metabolism
44Scoparia
45Weeds
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titleEssential Oil of Artemisia scoparia Inhibits Plant Growth by Generating Reactive Oxygen Species and Causing Oxidative Damage
authorSingh, Harminder Pal ; Kaur, Shalinder ; Mittal, Sunil ; Batish, Daizy Rani ; Kohli, Ravinder Kumar
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abstractWe investigated the chemical composition and phytotoxicity of the essential oil extracted from leaves of Artemisia scoparia Waldst. et Kit. (red stem wormwood, Asteraceae). GC/GC-MS analyses revealed 33 chemical constituents representing 99.83% of the oil. The oil, in general, was rich in monoterpenes that constitute 71.6%, with β -myrcene (29.27%) as the major constituent followed by (+)-limonene (13.3%), ( Z )- β -ocimene (13.37%), and γ -terpinene (9.51%). The oil and β -myrcene were evaluated in a dose–response bioassay under laboratory conditions for phytotoxicity against three weeds— Avena fatua, Cyperus rotundus , and Phalaris minor . A significant reduction in germination, seedling growth, and dry matter accumulation was observed in the test weeds. At the lowest treatment of 0.07 mg/ml Artemisia oil, germination was reduced by 39%, 19%, and 10.6% in C. rotundus, P. minor , and A. fatua , respectively. However, the inhibitory effect of β -myrcene was less. In general, a dose-dependent effect was observed and the growth declined with increasing concentration. Among the three weeds, the inhibitory effect was greatest on C. rotundus , so it was selected for further studies. We explored the explanation for observed growth inhibition in terms of reactive oxygen species (ROS: lipid peroxidation, membrane integrity, and amounts of conjugated dienes and hydrogen peroxide)-induced oxidative stress. Exposure of C. rotundus to Artemisia oil or β -myrcene enhanced solute leakage, indicating membrane disintegration. There were increased levels of malondialdehyde and hydrogen peroxide, indicating lipid peroxidation and induction of oxidative stress. We conclude that Artemisia oil inhibits plant root growth through generation of ROS-induced oxidative damage.
copNew York
pubSpringer-Verlag
pmid19194753
doi10.1007/s10886-009-9595-7