Comparative characteristics of Lupinus albus L. and Lupinus luteus L. under allelopathic effect of Sorghum halepense L. (Pers.)
Abstract
Allelopathic effects of aqueous extracts of Sorghum halepense L. (Pers.) on seed
germination and primary seedling growth and development of two lupine species
was studied. Lupinus albus and Lupinus luteus showed different levels of susceptibility
to the allelopathic effect of weed extracts. Increasing concentrations (1.25, 2.50, 5.00
and 10.00%) of extracts from aboveground and belowground biomass suppressed
seed germination of L. luteus from 53.2 to 74.7%. The germination of L. albus seeds was
unaffected, except by the highest concentration of 10.00%. Fresh biomass accumulation in the initial germ of L. luteus was inhibited by 3.8-40.3% under the effect of concentrations of 2.50, 5.00 and 10.00%, which made the species susceptible to S. halepense extracts. L. albus was tolerant as it was not found to sustain a significant allelopathic effect of the extracts.
References
Adetayo, O., Lawal, O., Alabi, B., & Owolade, O. (2005). Allelopathic effect of siam weed (Chromolaena odorata) on seed germination and seedling performance of selected crop and weed species. In Fourth World Congress on Allelopathy “Establishing the Scientific Basis”, Wagga Wagga (pp. 348-351). NSW, Australia: Charles Sturt University.
Alam, S.M., & Islam, E.U. (2002). Effects of aqueous extract of leaf, stem and root of nettleleaf goosefoot and NaCl on germination and seedling growth of rice. Pakistan Journal of Seed Technology, 1(2), 47-52.
Aleksieva, A., & Marinov-Serafimov, P. (2008). A study of allelopathic effect of Amaranthus retroflexus (L.) and Solanum nigrum (L.) in different soybean genotypes.
Herbologia, 9(2), 47-58.
AOSA. (1983). Seed vigor testing handbook (Contribution No. 32 to the Handbook on seed testing). Washington, DC: Association of Official Seed Analysis.
Butnariu, М., & Bostan, С. (2011). Antimicrobial and anti-inflammatory activities of the volatile oil compounds from Tropaeolum majus L. (Nasturtium). African Journal of Biotechnology, 10(31), 5900-5909. doi:10.5897/ajb11.264
Butnariu, М., Bostan, С., & Samfira, I. (2012) Determination of mineral contents and antioxidant activity in some plants that contain allelochemicals of Banat region (western Romania). Studia Universitatis „Vasile Goldis“ Arad, Seria Stiintele Vietii, 22, 95-100.
Butnariu, М., Goian, М., Ianculov, I., Gergen, I., & Negrea, Р. (2005). Studiu privind influenta ionului CO2+ asupra dezvoltarii si acumularii in plantele de soia a altor elemente chimice (fier, magneziu, calciu, potasiu si fosfor) [Studies about Co2+ ion influence on soy plants development and accumulation of other chemical elements (iron, magnesium, calcium, potassium and phosphorus)]. Revista de Chimie, 56(8), 837-841.
Chon, S.U., & Nelson, C.J. (2001) Effects of experimental procedures and conditions on bioassay sensitivity of lucerne autotoxicity. Communications in Soil Science and Plant Analysis, 32(9-10), 1607-1619. doi:10.1081/css-100104216
Dayan, F.E. (2006). Factors modulating the levels of the allelochemical sorgoleone in Sorghum bicolor. P1anta, 224(2), 339-346. doi:10.1007/s00425-005-0217-5
Dayan, F.E., Rimando, А.М., Раn, Z., Baerson, S.R., Gimsing, A.L., & Duke, S.O. (2010). Sorgoleone. Phytochemistry, 71(10), 1032-1039. doi:10.1016/j.phytochem.2010.03.011
Einhelling, F. A. (1996). Interactions involving allelopathy in cropping systems. Agronomy Journal, 88, 886-893. doi:10.2134/agronj1996.00021962003600060007x
Feng-Min, L., & Hong-Ying, H. (2005). Isolation and characterization of a novel antialgal allelochemical from Phragmites communis. Applied and Environmental Microbiology, 71(11), 6545-6553. doi:10.1128/AEM.71.11.6545-6553.2005
Gladstones, J. S. (1998). Distribution, origin, taxonomy, history and importance. In: J. S. Gladstones, C. A.Atkins & J. Hamblin (Eds.) Lupins as crop plants: Biology, production
and utilization (pp. 1-39). Wallingford, UK: CAB International Press.
Golubinova, I., & Georgieva, N. (2009). Study of allopathic effect of water extract of Vicia villosa (Roth.) on the initial development of different varieties Sorghum sudanense (Piper (Stapf.)). Plant Science, 46(6), 531-536.
Golubinova, I., & Ilieva, A. (2014). Allelopathic effects of water extracts of Sorghum halepense (L.) Pers., Convolvulus arvensis L. and Cirsium arvense Scop. on early seedling growth of some leguminous crops. Pesticidi i fitomedicina, 29(1), 35-43. doi:10.2298/pif1401035g
Hinnkelman, K., & Kempthorne, O. (1994). Design and analysis of experiments. New York, NY: Wiley and Sons.
Hobbs, R.J., Arico, S., Aronson, J., Barón, J.S., Bridgewater, Р., Cramer, V.А. … Zobel, М. (2006). Novel ecosystems: theoretical and management aspects of the new ecological world order. Global Ecology Biogeography, 15, 1-7. doi:10.1111/j.1466-822x.2006.00212.x
Holm, L.G., Plocknet, D.L., Pancho, J.V., & Herberger, J.P. (1977). The world’s worst weeds: Distribution and biology. Honolulu, HI: University Press of Hawaii.
Howard, J. (2004). Sorghum halepense. In: Fire effects information system. U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station, Fire Sciences Laboratory http://www.feis-crs.org/beta/
Kalinova, S., Golubinova, I., Hristoskov, A., & Ilieva, A. (2012). Allelopathic effect of aqueous extract from root systems of Johnson grass on seed germination and initial development of soybean, pea and vetch. Ratarstvo i povrtarstvo, 49(3), 250-256. doi:10.5937/ratpov49-1200
Kostov, K., & Pavlov, D. (1999) Fodder production. Plovdiv, Bulgaria: Academic Press of AU.
Lambers, H., Clements, J. C., & Nelson, M. N. (2013). How a phosphorus-acquisition strategy based on carboxylate exudation powers the success and agronomic potential of lupines (Lupinus, Fabaceae). American Journal of Botany, 100(2), 263-288. doi:10.3732/ajb.1200474
Liebman, M., & Sundberg, D.N. (2006). Seed mass affects the susceptibility of weed and crop species to phytotoxins extracted from red clover shoots. Weed Science, 54(2), 340-345.
Mamonov, L., & Kim, G. (1978 Matematičeskoe modelirovanie fiziologičeskih procesov u rastenij [Mathematical modeling of physiological processes of plants]. Alma Ata: ANL SSR: Institut botaniki.
Marinov-Serafimov, P. (2010) Determination of allelopathic effect of some invasive weed species on germination and initial development of grain legume crops. Pesticidi i fitomedicina, 25(3),251-259. doi:10.2298/pif1003251m
Marinov-Serafimov, P., & Dimitrova, Ts. (2007). Effect of weed extracts on the seed germination in some grain legumes. Herbologia, 8(1),11-22.
Marinov-Serafimov, P., Dimitrova, Ts., Golubinova, I., & Ilieva, A. (2007) Study of suitability of some solutions in allelopathic researches. Herbologia, 8(1), 1-10.
Mihovsky, Т., & Pachev, I. (2012). Reduced tillage practices. Banat’s Journal of Biotechnology, 3(6), 49-58. doi:10.7904/2068-4738-iii(6)-49
Moosavi, A., Afshari, R.T., Asadi, A., & Gharineh, M.H. (2011). Allelopathic effects of aqueous extract of leaf, stem and root of Sorghum bicolor on seed germination and seedling growth of Vigna radiate L. Notulae Scientia Biologicae, 3(2), 114-118.
Moyer, J.R., & Huang, H.C. (1997). Effect of aqueous extracts crop residues on seed germination and seedling growth of ten weed species. Botanical Bulletin of Academia
Sinica, 38, 131-139.
Nouri, H., Talab, Z.A., & Tavassoli, A. (2012). Effect of weed allelopathic of sorghum (Sorghum halepense) on germination and seedling growth of wheat, Alvand cultivar. Annals of Biological Research, 3(3), 1283-1293.
Plohinskij, N. (1967). Algoritmy biometrii (Algorithms of biometry (pp. 74-78). Moscow, SSSR: Publishing House of Moscow University
Putham, A.R., & Tang, C.S. (1986). The science of allelopathy. New York, NY: Wiley.
Rice, E.L. (1995). Biological control of weeds and plant disease: Advances in applied allelopathy. Norman OK: University of Oklahoma Press.
Sexton, J.Р., МсKау, J.K., & Sala, А. (2002). Plasticity and genetic diversity mау allow saltcedar to invade cold climates in North America. Есоlogical Applications, 12(6), 1652-1660. doi:10.1890/1051-0761(2002)012[1652:pagdma]2.0.co;2
Sikora, V. & Berenji, J. (2008). Alelopatski potencijal sirkova (Sorghum sp.) [Allelopathic potential of sorghums (Sorghum sp.)]. Bilten za hmelj, sirak i lekovito bilje,
(81), 5-15.
Singh, H.P., Batish, D.R., & Kohli, R.K. (2003). Allelopathic interactions and allelochemicals: New possibilities for sustainable weed management. Critical Reviews in Plant Sciences, 22(3-4), 239-311.
Stef, R., Bostan, C., Butu, A., Ortan, A., Rodino, S., & Butu, М. (2013). Comparative characteristics of Lupinus perennis L. under allelochemical sorgoleone stress. Romanian Biotechnological Letters, 18(3), 8327-8332.
Tinnin, R.O., & Muller, C.H. (1972). The allelopathic influence of Avena fatua: The allelopathic mechanism. Bulletin of the Torrey Botanical Club, 99(6), 287-292.
Tizazu, H., & Emire, S.A. (2010). Chemical composition, physicochemical and functional properties of lupin (Lupinus albus) seeds grown in Ethiopia. African Journal of Food Agriculture, Nutrition and Development, 10(8), 3029-3046. doi:10.4314/ajfand.v10i8.60895
Uddin, M.R., Park, K.W., Kim, Y.K, Park, S.U., & Pyon, J.Y. (2010). Enhancing sorgoleone levels in grain sorghum root exudates. Journal of Chemical Ecology, 36(8), 914-922. doi:10.1007/s10886-010-9829-8
Warwick, S.I., & Black, L.D. (1983). The biology of Canadian weeds: 61. Sorghum halepense (L.) Pers. Canadian Journal of Plant Science, 63(4), 997-1014. doi:10.4141/cjps83-125
Wolko, B., Clements, J. C., Naganowska, B., Nelson, M. N., & Yang, H. A. (2011) Lupinus. In C. Kole (Ed.), Wild crop relatives: Genomic and breeding resources (pp. 153-206). Berlin, Germany: Springer. doi:10.1007/978-3-642-14387-8_9
Wu, H., Pratley, J., Lemerle, D., Haig, T., & Verbeek, B. (1998). Differential allelopathic potential among wheat accessins to annual ryegrass. Proceedings of the 9th Australian Agronomy Conference, Wagga Wagga (pp. 567-571). Australia: Australian Society
of Agronomy.
Yang, Х., Owens, T.G., Scheffler, В.Е., & Weston, L.A. (2004). Manipulation of root hair development and sorgoleone production in sorghum seedlings. Journal of Chemical Ecolog y, 30(1), 199-213. doi:10.1023/b:joec.0000013191.35181.03
Authors retain copyright of the published papers and grant to the publisher the non-exclusive right to publish the article, to be cited as its original publisher in case of reuse, and to distribute it in all forms and media.
The published articles will be distributed under the Creative Commons Attribution ShareAlike 4.0 International license (CC BY-SA). It is allowed to copy and redistribute the material in any medium or format, and remix, transform, and build upon it for any purpose, even commercially, as long as appropriate credit is given to the original author(s), a link to the license is provided, it is indicated if changes were made and the new work is distributed under the same license as the original.
Users are required to provide full bibliographic description of the original publication (authors, article title, journal title, volume, issue, pages), as well as its DOI code. In electronic publishing, users are also required to link the content with both the original article published in Pesticidi i fitomedicina (Pesticides and Phytomedicine) and the licence used.
Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.