Contribution of non-target-site resistance in imidazolinone-resistant imisun sunflower

NESTARES, GRACIELA; ALTIERI, EMILIANO; BRECCIA, GABRIELA; BULOS, MARIANO; BULOS, MARIANO; GIL, MERCEDES; PICARDI, LILIANA; GIL, MERCEDES; VEGA, TATIANA; PICARDI, LILIANA; NESTARES, GRACIELA; VEGA, TATIANA; ALTIERI, EMILIANO; BRECCIA, GABRIELA

BRAGANTIA

Instituto Agronomico

Año: 2017 vol. 76 p. 536 - 542

0006-8705

The first commercial herbicide-resistant trait in sunflower (Helianthus annuus L.) is known as ?Imisun?. Imidazolinone resistance in Imisun cultivars has been reported to be genetically controlled by a major gene (known as Imr1 or Ahasl1-1) and modifier genes. Imr1 is an allelic variant of the Ahasl1 locus that codes for the acetohydroxyacid synthase, which is the target site of these herbicides. The mechanism of resistance endowed by modifier genes has not been characterized and it could be related to non-target-site resistance. The objective of this study was to evaluate the role of cytochrome P450 monooxygenases (P450s) in Imisun resistance. The response to imazapyr herbicide in combination with P450s inhibitor malathion was evaluated in 2 Imisun lines, IMI-1 and RHA426. Malathion reduced herbicide efficacy in both lines, but IMI-1 was affected in a greater extent. A significant reduction in plant growth in response to P450s inhibitors 1-aminobenzotriazole and piperonyl butoxide treatment was detected in the Imisun line HA425. The increased susceptibility to imazapyr after P450s-inhibitor treatment indicates that herbicide metabolism by P450s is a mechanism involved in Imisun resistance. These results also suggest the involvement of different P450s isozymes in endowing resistance to imazapyr in Imisun cultivars.