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Competitiveness and Essential Oil Phytotoxicity of Seven Annual Aromatic Plants

Published online by Cambridge University Press:  20 January 2017

Kico Dhima*
Affiliation:
Department of Plant Production, Technological and Educational Institute of Thessaloniki, 574 00 Echedoros, Greece
Ioannis Vasilakoglou
Affiliation:
Department of Plant Production, Technological and Educational Institute of Larissa, 411 10 Larissa, Greece
Vassiliki Garane
Affiliation:
Department of Food Technology, Technological and Educational Institute of Thessaloniki, 574 00 Echedoros, Greece
Christos Ritzoulis
Affiliation:
Department of Food Technology, Technological and Educational Institute of Thessaloniki, 574 00 Echedoros, Greece
Vaia Lianopoulou
Affiliation:
Department of Plant Production, Technological and Educational Institute of Thessaloniki, 574 00 Echedoros, Greece
Eleni Panou-Philotheou
Affiliation:
Department of Plant Production, Technological and Educational Institute of Thessaloniki, 574 00 Echedoros, Greece
*
Corresponding author's E-mail: [email protected]

Abstract

Crops that effectively compete with weeds may be more suitable in low-input agricultural systems. A 2-yr field experiment was conducted in northern Greece to assess the competitiveness of seven annual aromatic plants (anise, sweet fennel, sweet basil, dill, coriander, parsley, and lacy phacelia) on common purslane, common lambsquarters, black nightshade, and barnyardgrass. The phytotoxicity of the essential oils produced by these aromatic plants was also determined using a perlite-based bioassay with barnyardgrass. Separation, identification, and quantification of the volatile compounds of these essential oils were also performed. After the harvest of the aromatic plants (8 wk after planting), the greatest weed fresh weight reduction (94 to 100%) was recorded in lacy phacelia, whereas the least (0 to 30%) was recorded in parsley. Lacy phacelia and sweet fennel produced the greatest fresh biomass yield in weedy and weed-free treatments, whereas parsley, dill, and coriander produced the lowest. Biomass of sweet fennel and anise was reduced by only 9 to 11% by weed competition, whereas biomass of lacy phacelia was not significantly affected. The essential oils isolated from sweet fennel and sweet basil were the most phytotoxic on barnyardgrass, whereas those isolated from lacy phacelia and anise were the least phytotoxic. Conclusively, aromatic plants with great competitiveness such as lacy phacelia, anise, and sweet fennel provided great weed suppression and they could be cultivated with low inputs in herbicides. However, high competitiveness of aromatic plants may not always be correlated with high essential oil phytotoxicity.

Type
Weed Management
Copyright
Copyright © Weed Science Society of America 

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References

Literature Cited

An, M., Pratley, J. E., Haig, T., and Liu, D. L. 2005. Whole-range assessment: a simple method for analysing allelopathic dose-response data. Nonlin. Biol. Toxicol. Med. 3:245259.Google Scholar
Azeez, S. 2008. Fennel. Pages 227241. In Parthasarathy, V. A., Chempakam, B., and Zachariah, T. J. eds. Chemistry of Spices. Wallingford, CT CABI.Google Scholar
Azeez, S. and Parthasarathy, V. A. 2008. Parsley. Pages 376400. In Parthasarathy, V. A., Chempakam, B., and Zachariah, T. J. eds. Chemistry of Spices. Wallingford, CT CABI.Google Scholar
Baum, S. F., Karanastasis, L., and Rost, T. L. 1998. Morphogenetic effects of the herbicide Cinch on Arabidopsis thaliana root development. J. Plant Growth Regul. 17:107114.Google Scholar
Bielinski, S. M., Dusky, J. A., Stall, W. M., Shilling, D. G., and Bewick, T. A. 1997. Influence of smooth pigweed and common purslane densities on lettuce yields as affected by phosphorus fertility. Proc. Fla. State Hort. Soc. 110:315317.Google Scholar
Blank, I. and Grosch, W. 1991. Evaluation of potent odorants in dill seed and dill herb (Anethum graveolens L.) by aroma extract dilution analysis. J. Food Sci. 56:6367.Google Scholar
Blum, U., Shafer, S. R., and Lehman, M. E. 1999. Evidence for inhibitory allelopathic interactions involving phenolic acids in field soils: concepts vs. an experimental model. Crit. Rev. Plant Sci. 18:673693.Google Scholar
Chaimovitsh, D., Abu-Abied, M., Behausov, E., Rubin, B., Dudai, N., and Sadot, E. 2010. Microtubules are an intracellular target of the plant terpene citral. Plant J. 61:399408.Google Scholar
Chevallier, A. 1996. The Encyclopedia of Medicinal Plants. New York DK Publishing. 250 p.Google Scholar
Cserni, I. 1994. The effect of nutrients and variety on keeping quality during storage of fennel (Foeniculum vulgare Mill. subsp. Capillaceaum Gilib. var. Azoricum). Acta Hortic. 468:185189.CrossRefGoogle Scholar
Daferera, D. J., Ziogas, B. N., and Polissiou, M. G. 2003. The effectiveness of plant essential oils on the growth of Botrytis cinerea, Fusarium sp. and Clevibacter michiganensis subsp. michiganensis . Crop Prot. 22:3944.CrossRefGoogle Scholar
Damanakis, M. E. 1983. Weed species in wheat fields of Greece—1982, 1983 survey. Zizaniology. 1:8590.Google Scholar
Dhima, K. V., Vasilakoglou, I. B., Eleftherohorinos, I. G., and Lithourgidis, A. S. 2006. Allelopathic potential of winter cereals and their cover crop mulch effect on grass weed suppression and corn development. Crop Sci. 46:345352.CrossRefGoogle Scholar
Dhima, K. V., Vasilakoglou, I. B., Gatsis, Th D., Panou-Philotheou, E., and Eleftherohorinos, I. G. 2009. Effects of aromatic plants incorporated as green manure on weed and maize development. Field Crops Res. 110:235241.CrossRefGoogle Scholar
Dudai, N., Poljakoff-Mayber, A., Mayer, A. M., Putievsky, E., and Lerner, H. R. 1999. Essential oils as allelochemicals and their potential use as bioherbicides. J. Chem. Ecol. 25:10791089.Google Scholar
Elakovich, S. D. 1988. Terpenoids as models for new agrochemicals. Pages 250261. In Cutler, H. G. ed. Biologically Active Natural Products—Potential Use in Agriculture. Washington, DC American Chemical Society.Google Scholar
Gilbert, C. A., Stall, W. M., Chase, C. A., and Charudattan, R. 2008. Season-long interference of American black nightshade with watermelon. Weed Technol. 22:186189.Google Scholar
Inderjit, , and Keating, K. I. 1999. Allelopathy: principles, procedures, progresses, and promises for biological control. Adv. Agron. 67:141231.Google Scholar
Ismaiel, A. A. and Pierson, M. D. 1990. Inhibition of germination, outgrowth, and vegetative growth of Clostridium botulinum 67B by spice oils. J. Food Prot. 53:755758.Google Scholar
Isman, B. M. 2000. Plant essential oils for pest and disease management. Crop Prot. 19:603608.CrossRefGoogle Scholar
Karamanoli, K., Vokou, D., Menkissoglou, U., and Constantinidou, H-I. 2000. Bacterial colonization of phyllosphere of Mediterranean aromatic plants. J. Chem. Ecol. 26:20352048.Google Scholar
Khah, E. M. 2009. Effect of sowing date and cultivar on leaf yield and seed production of coriander (Coriandrum sativum L.). J. Food Agric. Environ. 7:332334.Google Scholar
Koschier, E. H. and Sedy, K. A. 2003. Labiate essential oils affecting host selection and acceptance of Thrips tabaci lindeman. Crop Prot. 22:929934.Google Scholar
Koutsos, Th 2006. Aromatic and Medicinal Plants. Thessaloniki, Greece Ziti Press. 352 p. [in Greek].Google Scholar
Leela, N. K. and Vipin, T. M. 2008. Aniseed. Pages 331341. In Parthasarathy, V. A., Chempakam, B., and Zachariah, T. J. eds. Chemistry of Spices. Wallingford, CT CABI.Google Scholar
Liu, D. L., An, M., and Wu, H. 2007. Implementation of WESIA: whole-range evaluation of the strength of inhibition in allelopathic bioassay. Allelop. J. 19:203214.Google Scholar
Mukhopadhyay, M. 2000. Natural Extracts Using Supercritical Carbon Dioxide. New York CRC Press. 342 p.Google Scholar
Omidbaigi, R., Sefidkon, F., and Kazemi, F. 2004. Influence of drying methods on the essential oil content and composition of Roman chamomile. Flav. Fragr. J. 19:196198.Google Scholar
Parthasarathy, V. A. and Zachariah, T. J. 2008. Coriander. Pages 190210. In Parthasarathy, V. A., Chempakam, B., and Zachariah, T. J. eds. Chemistry of Spices. Wallingford, CT CABI.Google Scholar
Petropoulos, S. A., Akoumianakis, C. A., and Passam, H. C. 2006. Evaluation of turning-rooted parsley (Petroselium crispum ssp. tuberosum) for root and foliage production under a warm, Mediterranean climate. Sci. Hortic. Amsterdam. 109:282287.Google Scholar
Petropoulos, S. A., Daferera, D., Akoumianakis, C. A., Passam, H. C., and Polissiou, M. G. 2004. The effect of sowing date and growth stage on the essential oil composition of three types of parsley (Petroselium crispum). J. Sci. Food Agric. 84:16061610.CrossRefGoogle Scholar
Ravid, U., Putievsky, E., Katzir, I., Lewinsohn, E., and Dudai, N. 1997. Identification of (1R)-(+)-verbenone in essential oils of Rosmarinus officinalis L. Flav. Frag. J. 12:109112.Google Scholar
Rizvi, S. H. and Rizvi, V. 1992. Allelopathy—Basic and Applied Aspects. 1st ed. London Chapman and Hall. 480 p.Google Scholar
Romagni, J. G., Allen, S. N., and Dayan, F. E. 2000. Allelopathic effects of volatile cineoles on two plant species. J. Chem. Ecol. 26:303313.Google Scholar
Serrato-Valenti, G., Cornara, L., Modenesi, P., Piana, M., and Mariotti, M. G. 2000. Structure and histochemistry of embryo envelope tissues in the mature dry seed and early germination of Phacelia tanacetifolia . Ann. Bot. London. 85:625634.Google Scholar
Singh, G., Maurya, S., de Lampasona, M. P., and Catalan, C. A. N. 2006. Studies on essential oils, part 41. Chemical composition, antifungal, antioxidant and sprout suppressant activities of coriander (Coriandrum sativum) essential oil and its oleoresin. Flav. Frag. J. 21:472479.Google Scholar
Singh, H. P., Batish, D. R., Setia, N., and Kohli, R. K. 2005. Herbicidal activity of volatile oils from Eucalyptus citriodora against Parthenium hysterophorus . Ann. Appl. Biol. 146:8994.Google Scholar
Smallfield, B. M., Perry, N. B., Beauregard, D. A., Foster, L. M., and Dodds, K. G. 1984. Effects of postharvest treatments on yield and composition of coriander herb oil. J. Agric. Food Chem. 42:354359.Google Scholar
Tunçw, I. and Şahinkaya, S. 1998. Sensitivity of two greenhouse pests to vapours essential oils. Entomol. Exp. Appl. 86:183187.Google Scholar
Tworkoski, T. 2002. Herbicide effects of essential oils. Weed Sci. 50:425431.Google Scholar
Vasilakoglou, I., Dhima, K., Wogiatzi, E., Eleftherohorinos, I., and Lithourgidis, A. 2007. Herbicidal potential of essential oils of oregano or marjoram (Origanum spp.) and basil (Ocimum basilicum) on Echinochloa crus-galli (L.) P. Beauv. and Chenopodium album L. weeds. Allelop. J. 20:297306.Google Scholar
Vengris, J. and Stacewicz-Sapuncakis, M. 1971. Common purslane competition in table beets and snap beans. Weed Sci. 19:46.Google Scholar
Venskutonis, P. R. 1997. Effect of drying on the volatile constituents of thyme (Thymus vulgaris L.) and sage (Salvia officinalis L.). Food Chem. 59:219227.Google Scholar
Vokou, D. 2007. Allelochemicals, allelopathy and essential oils: a field in search of definitions and structure. Allelop. J. 19:119134.Google Scholar
Vokou, D. and Liotiri, S. 1999. Simulation of soil microbial activity by essential oils. Chemoecology. 9:4145.Google Scholar
Watson, P. R., Derksen, D. A., and Van Acker, R. C. 2006. The ability of 29 barley cultivars to compete and withstand competition. Weed Sci. 54:783792.Google Scholar
Zheljazkov, V. D., Callahan, A., and Cantrell, C. L. 2008. Yield and oil composition of 38 basil (Ocimum basilicum L.) accessions grown in Mississippi. J. Agric. Food Chem. 56:241245.Google Scholar
Zimdahl, R. L. 2007. Fundamentals of Weed Science. 3rd ed. New York Elsevier. 666 p.Google Scholar