Conyza species: distribution and evolution of multiple target-site herbicide resistances
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- 作者:Maor Matzrafi ; Tzipora W. Lazar ; Moshe Sibony ; Baruch Rubin
- 关键词:ALS ; PSII ; Multiple herbicide resistance ; Horseweed ; Hairy fleabane
- 刊名:Planta
- 出版年:2015
- 出版时间:July 2015
- 年:2015
- 卷:242
- 期:1
- 页码:259-267
- 全文大小:721 KB
- 参考文献:Arntz AM, Delucia EH, Jordan N (2000) Fitness effects of a photosynthetic mutation across contrasting environments. J Evol Biol 13:792-03View Article
Ashigh J, Tardif FJ (2011) Water and temperature stress impact fitness of acetohydroxyacid synthase–inhibiting herbicide-resistant populations of eastern black nightshade (Solanum ptychanthum). Weed Sci 59:341-48View Article
Blondel J, Aronson J (1999) Biology and wildlife of the Mediterranean region. Oxford, New York, pp 328
Danin A (2014) Flora of Israel Online. Available at http://?www.?Flora.?Huji.?Ac.?Il . Accessed Jan 2014
Dauer JT, Mortensen DA, Humston R (2006) Controlled experiments to predict Horseweed (Conyza canadensis) dispersal distances. Weed Sci 54:484-89View Article
Dekker JH, Burmester RG (1992) Pleiotropy in triazine-resistant Brassica napus: ontogenetic and diurnal influences on photosynthesis. Plant Physiol 100:2052-058PubMed Central PubMed View Article
Fuerst EP, Nakatani HY, Dodge AD, Penner D, Arntzen CJ (1985) Paraquat resistance in conyza. Plant Physiol 77:984-89PubMed Central PubMed View Article
Hall TA (1999) BioEdit: a user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. Nucleic Acids Symp Ser 41:95-8
Heap IM (2014) International survey of herbicide-resistant weeds. Available at http://?www.?weedscience.?org Accessed Jan 2014
Hirschberg J, Mcintosh L (1985) Molecular basis of herbicide resistance in Amaranthus hybridus. Science 23:1346-349
Lehoczki E, Laskay G, P?l?s E, Mikulás J (1984) Resistance to triazine herbicides in horseweed (Conyza canadensis). Weed Sci 32:669-74
Lior E, Kigel J, Rubin B (1994) Variation in response of Conyza species to atrazine, diuron and sulfometuron. In: Proceedings of the 13th Weed Science Society of Israel Conference. Weed Science Society of Israel, Rehovot, p 134
Maxwell BD, Roush ML, Radosevich SR (1990) Predicting the evolution and dynamics of herbicide resistance in weed populations. Weed Technol 4:2-3
Mechant E, Demarez T, Herman O, Bulcke R (2008) Resistance of Chenopodium album to photosystem II-inhibitors. Commun Agric Appl Biol Sci 73:913-17PubMed
Mengistu LW, Mueller-Warrant GW, Liston A, Barker RE (2000) psbA Mutation (valine 219 to isoleucine) in Poa annua resistant to metribuzin and diuron. Pest Manag Sci 56:209-17View Article
Mengistu LW, Christoffers MJ, Lym RG (2005) A psbA mutation in Kochia scoparia (L) Schrad from railroad rights-of-way with resistance to diuron, tebuthiuron and metribuzin. Pest Manag Sci 61:1035-042PubMed View Article
Norsworthy JK, Ward SM, Shaw DR, Llewellyn RS, Nichols RL, Webster TM, Bradley KW, Frisvold G, Powles SB, Burgos NR, Witt WW, Barrett M (2012) Reducing the risks of herbicide resistance: best management practices and recommendations. Weed Sci 60:31-2View Article
Park KW, Mallory-Smith CA (2006) psbA mutation (Asn 266 to Thr) in a Senecio vulgaris L. confers resistance to several PSII-inhibiting herbicides. Pest Manag Sci 62:880-85PubMed View Article
Perez-Jones A, Intanon S, Mallory-Smith C (2009) Molecular analysis of hexazinone-resistant shepherd’s-purse (Capsella bursa-pastoris) reveals a novel psbA mutation. Weed Sci 57:574-78View Article
Plowman AB, Richards AJ, Tremayne MA (1999) Environmental effects on the fitness of triazine-resistant and triazine-susceptible Brassica rapa and Chenopodium album in the absence of herbicide. New Phytol 141:471-85View Article
Rubin B (1997) Herbicide resistance outside North America and Europe: causes and significance. In: Weed and Crop Resistance to Herbicides. Kluwer Academic Publishers, Dordrecht, pp 39-2
Rubin B, Yaacoby T, Schonfeld M (1985) Triazine resistant grass weeds: cross resistance with wheat herbicide, a possible threat to cereal crops. In: Proceedings of the British Crop Protection Conference - Weeds, Brighton Metropole, England, pp 1171-178
Rubin B, Tal A, Yasuor H (2004) The significance and impact of herbicide resistance weeds—a global overview. Acta Herbol 13:277-88
Seefeldt SS, Jensen JE, Fuerst EP (1995) Feature log-logistic analysis of herbicide dose-response relationships. Weed Technol 9:218-27
Sibony M, Rubin B (2003) Molecular basis for multiple resistance to acetolactate synthase-inhibiting herbicides and atrazine in Amaranthus blitoides (prostrate pigweed). Planta 216:1022-027PubMed
Tardif FJ, Rajcan I, Costea M (2006) A mutation in the herbicide target site acetohydroxyacid synthase produces morphological and structural alterations and reduces fitness in Amaranthus powellii. New Phytol 169:251-64PubMed View Article
Thiel H, Varrelmann M (2014) Identification of a new PSII target site psbA mutation leading to D1 amino acid Leu218 Val exchange in the Chenopodium album D1 protein and comparison to cross-resistance profiles of known modifications at positions 251 and 264. Pest Manag Sci 70:278-85PubMed View Article
Trainer GD, L - 作者单位:Maor Matzrafi (1)
Tzipora W. Lazar (1)
Moshe Sibony (1)
Baruch Rubin (1)
1. The Robert H. Smith Institute of Plant Sciences and Genetics in Agriculture, The Hebrew University of Jerusalem, PO Box 12, 7610001, Rehovot, Israel - 刊物主题:Plant Sciences; Agriculture; Ecology; Forestry;
- 出版者:Springer Berlin Heidelberg
- ISSN:1432-2048
文摘
Main conclusion Distribution of Conyza species is well correlated with human interference. Multiple herbicide resistance is caused by the attempt to overcome resistance to one mode of action by overuse of another. Conyza canadensis (CC) and Conyza bonariensis (CB) are troublesome weeds around the world. Extensive use of herbicides has led to the evolution of numerous Conyza spp. herbicide-resistant populations. Seeds of 91 CC and CB populations were collected across Israel. They were mostly found (86?%) in roadsides and urban habitats, two disturbed habitats that had been dramatically impacted by human activities, thus we classify these species as anthropogenic. Although pyrithiobac-sodium was only used in cotton fields, 90?% of Conyza spp. populations were identified as pyrithiobac-sodium resistant, suggesting possible natural resistance to pyrithiobac-sodium. CC21 and CC17 C. canadensis populations were highly resistant to all tested ALS inhibitors due to a substitution in the ALS gene from Trp574 to Leu. They were also atrazine resistant due to a substitution in the psbA gene from Ser264 to Gly. The high level of imazapyr and pyrithiobac-sodium resistance observed in the CC10 population was due to an Ala205 to Val substitution. However, high resistance to sulfometuron methyl and pyrithiobac-sodium in population CC6 was due to a point mutation at Pro197 to Ser. All resistant plants of CC21 population showed both psbA (Ser264 to Gly) and ALS (Trp574 to Leu) substitutions, leading us to the conclusion that the attempt to overcome resistance to one mode of action by overuse of another will most likely lead to multiple herbicide resistance. Furthermore, we concluded that only individuals that carry both mutations could survive the shift between the two modes of action and overcome the fitness cost associated with the PSII resistance.