BACKGROUND: Chloris virgata is a warm-season, C4 , annual grass weed affecting field crops in northern Australia that has become an emerging weed in southern Australia. Four populations with suspected resistance to glyphosate were collected in South Australia, Queensland and New South Wales, Australia, and compared with one susceptible (S) population to confirm glyphosate resistance and elucidate possible mechanisms of resistance. RESULTS: Based on the rate of glyphosate required to kill 50% of treated plants (LD50 ), glyphosate resistance (GR) was confirmed in four populations of C. virgata (V12, V14.2, V14.16 and V15). GR plants were 2-9.7-fold more resistant and accumulated less shikimate after glyphosate treatment than S plants. GR and S plants did not differ in glyphosate absorption and translocation. Target-site EPSPS mutations corresponding to Pro-106-Leu (V14.2) and Pro-106-Ser (V15, V14.16 and V12) substitutions were found in GR populations. The population with Pro-106-Leu substitution was 2.9-4.9-fold more resistant than the three other populations with Pro-106-Ser substitution. CONCLUSION: This report confirms glyphosate resistance in C. virgata and shows that target-site EPSPS mutations confer resistance to glyphosate in this species. The evolution of glyphosate resistance in C. virgata highlights the need to identify alternative control tactics.
BACKGROUND:Chloris virgata is a warm-season, C4 , annual grass weed affecting field crops in northern Australia that has become an emerging weed in southern Australia. Four populations with suspected resistance to glyphosate were collected in South Australia, Queensland and New South Wales, Australia, and compared with one susceptible (S) population to confirm glyphosate resistance and elucidate possible mechanisms of resistance. RESULTS: Based on the rate of glyphosate required to kill 50% of treated plants (LD50 ), glyphosate resistance (GR) was confirmed in four populations of C. virgata (V12, V14.2, V14.16 and V15). GR plants were 2-9.7-fold more resistant and accumulated less shikimate after glyphosate treatment than S plants. GR and S plants did not differ in glyphosate absorption and translocation. Target-site EPSPS mutations corresponding to Pro-106-Leu (V14.2) and Pro-106-Ser (V15, V14.16 and V12) substitutions were found in GR populations. The population with Pro-106-Leu substitution was 2.9-4.9-fold more resistant than the three other populations with Pro-106-Ser substitution. CONCLUSION: This report confirms glyphosate resistance in C. virgata and shows that target-site EPSPS mutations confer resistance to glyphosate in this species. The evolution of glyphosate resistance in C. virgata highlights the need to identify alternative control tactics.
Authors: Enzo R Bracamonte; Pablo T Fernández-Moreno; Fernando Bastida; María D Osuna; Ricardo Alcántara-de la Cruz; Hugo E Cruz-Hipolito; Rafael De Prado Journal: Front Plant Sci Date: 2017-11-15 Impact factor: 5.753
Authors: Javid Gherekhloo; Pablo T Fernández-Moreno; Ricardo Alcántara-de la Cruz; Eduardo Sánchez-González; Hugo E Cruz-Hipolito; José A Domínguez-Valenzuela; Rafael De Prado Journal: Sci Rep Date: 2017-07-27 Impact factor: 4.379