Late watergrass (Echinochloa phyllopogon): mechanisms involved in the resistance to fenoxaprop-p-ethyl.

Fenoxaprop-p-ethyl (FE), 2-[4-[(6-chloro-2-benzoxazolyl)oxy]phenoxy] propanoate, ethyl ester (R), is an aryloxyphenoxypropionate herbicide for postemergence control of annual and perennial grasses in paddy fields; its site of action is acetyl-coenzyme A carboxylase (ACCase), an enzyme in fatty acids biosynthesis. The possible mechanism(s) of resistance to FE in a resistant biotype of Echinochloa phyllopogon was examined, namely, absorption, translocation, and metabolism of FE and ACCase susceptibility to fenoxaprop acid (FA). Studies of the in vitro inhibition of ACCase discounted any differential active site sensitivity as the basis of resistance to FE. There were differences in absorption rates between biotypes from 3 to 48 h after application (HAA). Biotypes did not differ in either the amounts or the rates of FE translocated; 98% of applied [14C]FE remaining in the treated leaf. However, there was a good correlation between the rate of herbicide metabolism and the plant resistance. The R biotype produced 5-fold less FA and approximately 2-fold more nontoxic (polar) metabolites 48 HAA than the S biotype. Moreover, the higher rate of GSH conjugation in the resistant biotype as compared to the susceptible one indicates that GSH and cysteine conjugation is the major mechanism of resistance of the R biotype against FE toxicity.

Evaluation of resistance in Cyperus difformis populations to ALS inhibiting herbicides.

Due to the intensification of rice cultivation in Spain and the repeated use of herbicides as an effective tool to control weeds, one important fact is the appearance of resistant populations of weeds, which are no longer controlled effectively at field doses. Therefore, it is necessary to increase doses to such an extent as to produce phytotoxicity in the rice crop. In paddy fields in Badajoz (Spain), a few years ago, populations of Cyperus difformis resistant to bensulfuron-methyl appeared. In order to characterize this resistance, whole plant assays were carried out in fourteen populations, eight of them originating from treated Spanish paddy fields. The results were expressed as resistance factor (RF) = ED50(R)/ED50(S). Two populations of Cyperus difformis, resistant (R) and tolerant (T) to bensulfuron-methyl, displayed resistance factors greater than 30 and 12.5, respectively. Furthermore, in order to evaluate the existence of a possible cross-resistance, the recommended field doses of 3 other herbicides (imazamox, ethoxysulfuron and bentazone + MCPA) were applied to the plants. All populations were susceptible to both imazamox and bentazone + MCPA and two populations showed cross-resistance to ethoxysulfuron. ALS activity was assayed in vitro in four biotypes, the R/S ratios of the I50 values calculated indicate that resistance involves a reduction in the sensitivity of the ALS mainly in the R population (biotype 4) to bensulfuron-methyl and ethoxysulfuron, displaying R/S ratios of 37500 and 142857, respectively, which may be attributed to inherent differences in the ALS protein itself and/or in the stability of the enzyme.

Cross resistance to accase herbicide in Lolium rigidum.

Lolium rigidum is a cross-pollinating grass weed present in Europe and occurring in winter wheat and orchard crops. Several graminicides such as chlorotoluron and/or isoproturon and diclofop-methyl in mixtures or alone have been used successfully to control this weed in Spain during the past decade. However, several L rigidum populations have developed resistance to these herbicides following selection due to their continuous use. Four resistance mechanisms have been found in this grass weed, an enhanced metabolic detoxiflcation of the herbicides and an insensitive isoform of ACCase being the most important ones. The extent of cross-resistance depends on the type of mechanism. The biotype with an enhanced metabolic detoxification showed cross-resistance to ACCase-, ALS-, PSII- and tubuline-inhibiting herbicides, while the biotype resistant due to a mutation of the target site (ACCase) presented cross-resistance to ACCase-inhibiting herbicides only.

Evaluation of resistance in Amaranthus quitensis Kunth populations to imazethapyr and other imidazolinones.

Six populations of Amaranthus quitensis (R1, R3-R7), taken from soybean fields in Córdoba (Argentina), continuously treated with imazethapyr escaped from control with this herbicide. In order to characterize this resistance, whole plant assays were carried out using imazethapyr. Treatments were made at different doses, from 0.5 g a.i.ha(-1) to 60 g a.i.ha(-1), at 200 1 ha(-1) and 200 kPa pressure. Shoot fresh weight was mesured 21 days after treatment. The results were expressed as resistance factor (ED50(R)/ED50(S)). Different degrees of resistance were found as its shown by the respective resistance factors: R1:22.5, R3:6.5, R4:43.1, R5:8.6, R6:4, R7:5. Due to the high variability in the response to imazethapyr treatments shown in some populations, and according to previous investigations on the ALS gene that proved heterozygosity a screening was made, at the recommended dose of imazethapyr. Plants were classified according to their state, dead, alive and affected (fallen but alive). Populations 3, 6 and 7 showed an important heterozygosity. Furthermore, in order to evaluate the existance of a possible cross-resistance, the recommended doses of 4 other imidazolinones (imazametabenz, imazapyr, imazamox, imazaquin) were applied to the plants. All populations were susceptible to both imazamox and imazapyr and showed cross-resistance to imazamethabenz and imazaquin.

Cross resistance to ALS-inhibiting herbicides in Euphorbia heterophylla L. biotypes resistant to imazethapyr.

The effect of weeds on the diminution of agricultural production is considered to be between 30 and 50%. Imazethapyr is a herbicide which acts on the enzyme ALS, the first common enzyme in the biosynthetic pathway of valine, leucine and isoleucine. Euphorbia heterophylla is a common species in soybean fields in Brazil and different populations resistant to herbicides of the sulfonylurea and imidazolinone groups are currently being reported. The objectives of this work were: to determine the resistance of three different biotypes named RI, RII and RII to the herbicide imazethapyr: to establish the level of resistance to this herbicide, and to evaluate the behaviour of the biotypes to other herbicides with a similar mode of action. The response of plants treated with imazethapyr confirmed the existence of resistance in the biotypes denominated as RI, RII and RIII. The imazethapyr concentration required to reduce the activity of the enzyme ALS by 50% (I50) should be greater than 500 microM for biotypes RI, RII and RIII and 39.47 microM for the susceptible biotype. Applications made in the greenhouse at field doses of ALS inhibiting herbicides showed cross resistance in the case of imazamox and imazamethabenz but not in the cases of the other ALS inhibitor herbicides used. ALS activity results demonstrated that the imazethaphyr resistance in different biotypes of E. heterophylla is target site mediated.