Characterization of mesosulfuron-methyl + iodosulfuron-methyl and pyroxsulam–resistant annual bluegrass (Poa annua) in an annual cropping system

Abstract Herbicide-resistant annual bluegrass (Poa annua L.) has become a problem in non-arable land areas. In arable fields, P. annua is frequently of lower priority in weed control program due to the variety of control options available and the relatively modest impact on crop yield compared with other species. In Ireland, postemergence herbicides are not primarily intended for P. annua control, but some herbicides, including the acetolactate synthase (ALS) inhibitor mesosulfuron-methyl + iodosulfuron-methyl, exhibit P. annua activity. In this study, a suspected P. annua population (POAAN-R) that survived mesosulfuron-methyl + iodosulfuron-methyl at 0.75 of the field recommended rate was sampled from a wheat (Triticum aestivum L.) field in County Dublin, Ireland. Single-dose testing confirmed that the suspected POAAN-R had evolved resistance to mesosulfuron-methyl + iodosulfuron-methyl and, additionally, to pyroxsulam (not registered in Ireland for P. annua control), but was sensitive to clethodim, glyphosate, pendimethalin, and flufenacet. Dose–response experiments indicated that POAAN-R was more resistant (GR50 resistance index) to both mesosulfuron-methyl + iodosulfuron-methyl (47.8 times) and pyroxsulam (38.0 times) than sensitive POAAN-S, and this was associated with the mutation at Trp-574 in the ALS protein. Malathion (a cytochrome P450 [P450] inhibitor) pretreatment did not reverse POAAN-R resistance to mesosulfuron-methyl + iodosulfuron-methyl or pyroxsulam at the field rate or above. The natural inherent mutation at Ile-1781 in acetyl-CoA carboxylase protein had no effect on both POAAN-R and POAAN-S sensitivity to clethodim. The glyphosate sensitivity of POAAN-R also corresponded with no known mutation in 5-enolpyruvylshikimate-3-phosphate synthase protein. Based on field histories, poor early-season weed control coupled with intensive use of mesosulfuron-methyl + iodosulfuron-methyl (often at reduced rates) has unintentionally selected for ALS inhibitor–resistant POAAN-R. This is the first report to characterize resistance in P. annua to ALS-inhibiting herbicides mesosulfuron-methyl + iodosulfuron-methyl and pyroxsulam in an arable setting. There is an opportunity to effectively control POAAN-R using herbicides, but this needs a wide-ranging and varied approach, coupled with cultural/nonchemical practices.


Introduction
In Europe, Irish agriculture is characterized by an Atlantic-influenced climate, with an average rainfall of 600 to 1,000 mm, annual sunshine of 1,100 to 1,600 h, and a soil quality legacy from historical mixed grassland/spring cereal cropping systems, which results in mean grain yields ranging from 7,200 (winter oats [Avena sativa L.]) to 10,700 (winter wheat [Triticum aestivum L.]) kg ha −1 , among the highest globally (CSO 2021;Forristal and Grant 2011;Met Eireann 2021;Vijayarajan et al. 2022).The mild damp climate is, however, conducive to the rapid growth and proliferation of grass weeds, fungal pathogens, and some insect vector-transmitted diseases, requiring the intensive use of crop protection chemicals, especially fungicides (15% of production costs per hectare) and herbicides (8%), to achieve high yield potential for cereal crops (Jess et al. 2014;Lynch et al. 2017;Teagasc 2022).In Ireland, annual bluegrass (also known as annual meadow grass; Poa annua L.) is abundant on all soils, including arable fields, grasslands, forests, gardens, lawns, roadside verges, wastelands, and amenity areas (Bond et al. 2007;Vijayarajan et al. 2022).It is primarily a selfpollinated, allotetraploid (2n = 28) weed, with high fecundity and germination rates (Bond et al. 2007;Carroll et al. 2021;Gardarin et al. 2009).In arable fields, P. annua populations tend to build up rapidly in early-sown winter cereals in all crop establishment systems, especially non-inversion tillage (Fortune et al. 2005).A recent grower survey of grass weeds in cereals in Ireland ranked P. annua as the third most problematic species after poverty brome (Bromus sterilis L.) and wild oats (Avena fatua L.) (Vijayarajan et al. 2022).Nevertheless, a low incidence of just 9% on 103 farms at preharvest coupled with very low population pressure means that growers consider P. annua relatively easy to control with a variety of herbicide options and timings available (i.e., preplant burndown, residual herbicides applied as preemergence/early postemergence and postemergence).
In Ireland, spring barley (Hordeum vulgare L.) (120,000 ha), winter wheat (60,000 ha), and winter barley (60,000 ha) are the most dominant cereal crops, along with broadleaf crops, including canola (Brassica napus L.) and field beans (Vicia faba L.) both 19,700 ha (CSO 2021).At least 388,509 ha of cereal, canola, and bean crops were herbicide treated in 2016, with 31% of this area treated with burndown glyphosate (Group 9: inhibitor of 5-enolpyruvylshikimate-3-phosphate synthase [EPSPS]), 5% with residual herbicides such as pendimethalin (Group 3: inhibitor of microtubule assembly), flufenacet or prosulfocarb (Group 15: inhibitors of very-long-chain fatty-acid synthesis), 26% with early or autumn postemergence isoproturon (Group 5: photosystem II inhibitor), and 38% with spring postemergence acetyl-CoA carboxylase (ACCase) (Group 1) and acetolactate synthase (ALS) (Group 2) inhibitors (DAFM 2016).The application of glyphosate is primarily targeted at the control of quackgrass [Elymus repens (L.) Gould] and/or B. sterilis, as well as volunteer cereals (Vijayarajan et al. 2022).Residual herbicides are used primarily for P. annua and broadleaf weeds or limited control of B. sterilis.ACCase/ALS-inhibiting herbicides are applied in cereals to control B. sterilis and/or A. fatua, and other grass weeds not controlled earlier; in broadleaf crops, they are used to control grass weeds and volunteer cereals (Vijayarajan et al. 2022).Among the most commonly used ACCase/ALS-inhibiting herbicides, ALS inhibitor mesosulfuron-methyl þ iodosulfuron-methyl, used in winter wheat, and ACCase inhibitor clethodim, used in winter canola, are also highly active on P. annua and are registered in Ireland for controlling this species (Anonymous 2017(Anonymous , 2022c)).Another ACCase graminicide, propaquizafop, used in broadleaf crops, may also have limited activity on P. annua only at early growth stages (Anonymous 2020).The herbicides ACCase inhibitor pinoxaden (used in barley and wheat) and cycloxydim (graminicide) as well as ALS inhibitor pyroxsulam (used in winter wheat) are not registered in Ireland for P. annua control (Anonymous 2018(Anonymous , 2022a(Anonymous , 2022d)).
In Ireland, frequent use of ACCase/ALS-inhibiting herbicides to control key grass weeds threatens future weed control in these regions, as it risks promoting target-site resistance (TSR) due to mutations in the target genes, and non-target site resistance (NTSR), predominately via enhanced metabolism (e.g., Torra et al. 2021;Yu and Powles 2014).Since 2019, resistance to ACCase/ALS inhibitors via TSR and/or NTSR has been documented in A. fatua and B. sterilis, as well as unintended targets such as black-grass (Alopecurus myosuroides L.) and Italian ryegrass [Lolium perenne L. ssp.multiflorum (Lam.)Husnot] in cereal fields in Ireland (Alwarnaidu Vijayarajan et al. 2020Vijayarajan et al. , 2021;;Byrne et al. 2021;Vijayarajan et al. 2022).Although the ACCase/ALS-inhibiting herbicides are usually not targeted to control P. annua in Ireland, the wet autumns and fewer preemergence spray opportunities and the loss of isoproturon registration in the European Union (EU) in 2017 resulted in more reliance on postemergence herbicides that also had activity on P. annua, raising the possibility of resistance development in non-target species.To date, no reports of herbicide resistance have been reported for P. annua in Ireland.Internationally, there are 49 reports of P. annua resistance, involving 10 different herbicide modes of action, including both TSR and NTSR mechanisms, resulting in P. annua being ranked the third most problematic weed from a resistance perspective (Heap 2023).However, all documented P. annua resistance cases in Europe and globally have occurred in non-arable crop situations (golf courses, orchards, turf, etc.), except for one mesosulfuronmethyl þ iodosulfuron-methyl-resistant case from a wheat crop in France, reported in 2015.It is worth noting that P. annua is known to exhibit natural tolerance to some ACCase herbicides, including propaquizafop, cycloxydim, and pinoxaden, due to the natural inheritance of the mutation at Ile-1781 in the ACCase protein (Barua et al. 2020;Clay et al. 2006;Délye and Michel 2005;Ghanizadeh et al. 2020).
Grass-weed challenges have increased in Ireland due to increased winter cropping, earlier autumn sowing, non-inversion tillage adoption, and new weed introductions from seed imports and spread via machinery moving from farm to farm (Vijayarajan et al. 2022).Consequently, Teagasc (the state-funded research and farm advisory organization) has developed a herbicide-resistance monitoring program through which a case of suspected resistance in P. annua (POAAN-R) to mesosulfuron-methyl þ iodosulfuronmethyl was received from a crop farm in County Dublin, Ireland; POAAN-R is the subject of this research.The main objectives of this research were to: (1) determine the occurrence and level of resistance exhibited by POAAN-R to mesosulfuron-methyl þ iodosulfuron-methyl and cross-resistance, if any, to another ALS chemistry, pyroxsulam; (2) verify the resistance mechanisms to ALS-inhibiting herbicides; and (3) evaluate the efficacy of other herbicide modes of action for controlling POAAN-R.In the context of EU policies (e.g., Directive 2009/128/EC Sustainable Use of Pesticides, Farm to Fork Strategy, 2030 Biodiversity Strategy), which aim to reduce chemical pesticide use and promote integrated pest management approaches (McGinley et al. 2023;Silva et al. 2022;Tataridas et al. 2022), this work is an essential component of a research approach needed to support a move to more sustainable integrated grass-weed management (IWM, cultural/nonchemical control, and judicious herbicide use) techniques.

Plant Material
Mature seeds of the suspected POAAN-R population that survived field application of 11.3 þ 3.9 g ai ha −1 of mesosulfuron-methyl þ iodosulfuron-methyl (0.75 of the recommended field rate of product Pacifica Plus, Bayer CropScience, Cambridge, UK) were collected before winter wheat harvest in July 2021 from a crop field (53.867°N, 6.6°W) located near Garristown, in County Dublin, Ireland.The field was managed for at least 11 yr using deep non-inversion tillage (tine and disk implements cultivate the soil and mix crop residue to 100-to 150-mm deep) with winter wheat grown in 4 of 5 yr in a rotation with 1 yr of canola or beans.The herbicide treatments always involved use of mesosulfuron-methyl þ iodosulfuronmethyl in winter wheat at lower rates, from 7.5 þ 2.5 g ha −1 to 11.3 þ 3.9 g ha −1 (0.5 to 0.75 of field recommended rates), and propaquizafop in broadleaf crops, used at 75 g ai ha −1 (0.5 of field recommended rate), primarily to control B. sterilis.Glyphosate was also used pre-sowing for grass-weed control on stubbles, at rates from 270 g ai ha −1 to 405 g ai ha −1 (0.5 to 0.75 of field recommended rates).Residual herbicides, including diflufenican (Group 12: inhibitors of phytoene desaturase) in winter wheat, pendimethalin þ imazamox (Group 3 and 2) in beans, or propyzamide (Group 3) in winter canola, were used early postemergence on some occasions.
A herbicide-sensitive P. annua population (POAAN-S) was obtained from a commercial seed supplier (WeberSeeds Botany & Ethnobotany, Vaals, Netherlands) to be used as a sensitive reference.Seeds from both populations were stored in paper bags at 15 C.

Growing Conditions and Herbicide Application
During the winter of 2022 to 2023, seeds of POAAN-R and POAAN-S populations were sown in 230 by 176 by 55 mm plastic trays filled with a standard soil mix containing 70% loam, 20% horticultural grit, 10% medium (Professional) peat, and 2 g l −1 Osmocote Mini ™ (National Agrochemical Distributors, Lusk,   County Dublin, Ireland).Each replicate had 15 to 20 seeds per tray.Seeds were covered with 1 cm of soil.Trays were watered as required throughout the experiment.Herbicide treatments were applied using a Generation III Research Track Sprayer (DeVries Manufacturing, Hollandale, MN, USA) with a TeeJet® 8002-EVS flat-fan nozzle (Spraying Systems, Wheaton, IL, USA), at a pressure of 250 kPa and a water volume equivalent of 200 L ha −1 .The postemergence treated and untreated control plants were grown in a glasshouse compartment with 18/12 C (day/night) temperature regime at a photoperiod of 16 h supplemented with artificial lighting to maintain a minimum light intensity of 250 μ mol m −2 s −1 .The preemergence treated and untreated control plants were grown in an unheated glasshouse compartment, mimicking outdoor growing conditions for optimum activity of the residual herbicides.

Single-Dose Herbicide-Resistance Testing
Two experiments were conducted using a variety of herbicides at recommended field rates (Table 1) to determine the sensitivity or resistance of POAAN-R.Experiment 1 evaluated two ALS inhibitors, while Experiment 2 tested three ACCase inhibitors, an EPSPS inhibitor, and the two most commonly used residual herbicides, pendimethalin and flufenacet.In this region, the ALS herbicides for grass-weed control are only available commercially as formulated mixtures to target a broad spectrum of species, including broadleaf weeds (Anonymous 2022a(Anonymous , 2022c)).The two ALS herbicides used in this research, contain a number of active ingredients of the same chemical family.Pacifica Plus (Bayer CropScience) contains a formulated mixture of mesosulfuron-methyl þ iodosulfuron-methyl þ amidosulfuron, and Broadway Star (Corteva Agrisciences, Cambridge, UK) contains a formulated mixture of pyroxsulam þ florasulam.The amidosulfuron component in Pacifica Plus and the florasulam component in Broadway Star are included to provide broadleaf weed control (Davies et al. 2020), as evidenced by the weed control information on the labels of products using amidosulfuron alone (e.g., product Eagle, Bayer CropScience, Cambridge, UK) or florasulam alone (e.g., product Lector, Nufarm, West Yorkshire, UK) (Anonymous 2022b(Anonymous , 2023)).Most growers rely on these two broad-spectrum postemergence ALS-inhibiting herbicides for spring-applied grass-weed (especially B. sterilis) control in winter wheat in Ireland (Alwarnaidu Vijayarajan et al. 2021).This research evaluated the efficacy of the active ingredients mesosulfuronmethyl þ iodosulfuron-methyl in Pacifica Plus and pyroxsulam in Broadway Star on P. annua.control.
Foliar application herbicides were applied postemergence at growth stage (GS) 12-13 (BBCH) (Hess et al. 1997).Residual herbicides were applied preemergence directly onto the seeds sown on moist soil (for herbicide activation) in trays on the same day of sowing.Immediately after spraying, seeds were covered with the soil to which preemergence herbicide was applied and not watered for 48 h.Each experiment consisted of four replicates of each herbicide treatment and nontreated control for each population and was repeated.
Plant survival posttreatment was assessed visually at 30 d and expressed as a percentage of the total number of treated plants.Based on a visual check, surviving plants that continued to produce new shoots or tillers after treatment were recorded as resistant, and plants with symptoms of severe leaf chlorosis, desiccation, or no new active growth, and ultimately total plant death, or plants that did not have at least one emergent leaf (preemergence only), were recorded as susceptible.

TSR Analysis
Fresh leaf samples from the youngest fully developed leaves of eight plants, 8 from POAAN-R that had survived the field recommended rate of mesosulfuron-methyl þ iodosulfuronmethyl (15 þ 5 g ha −1 ), and 8 from untreated control plants in POAAN-S were collected from the single-dose assays.DNA was extracted from a total of 16 leaf samples with the Macherey-Nagel Plant DNA Kit (Lab Unlimited -Carl Stuart Group, Tallaght, County Dublin, Ireland) using the ThermoScientific TM Pharma Kingfisher TM flex 96 Deep-well head magnetic particle processor Weed Science (Lab Unlimited -Carl Stuart Group).The DNA concentration of each sample was determined using the Quanti-iT TM PicoGreen TM dsDNA Assay kit (Invitrogen TM ) (Bio-Sciences Limited, Dun Laoghaire, County Dublin, Ireland) and then each diluted to 20 ng μl −1 .A sealed elusion plate containing DNA solutions was sent to a commercial company (IDENTXX, Stuttgart, Germany) for TSR genotyping.The samples were analyzed for the most common mutations in the ALS gene at positions  for the ACCase gene at positions Ile-1781, Trp-2027, lle-2041, Asp-2078, and Gly-2096;and for the EPSPS gene at position Pro-106; all of which were identified mutations associated with herbicide resistance in grass-weed species (e.g., Brunharo et al. 2019;Tranel and Wright 2002;Yu et al. 2007).Briefly, the polymerase chain reaction (PCR) was performed on the genomic DNA (5 to 10 ng μl −1) using specific primers (developed by IDENTXX, Stuttgart, Germany) for amplification of the ALS, ACCase, and EPSPS gene fragments covering the positions of interest.PCR products of respective gene fragments were amplified using initial denaturation for 3 min at 95 C, followed by 40 cycles consisting of 95 C for 10 s, 52 to 62 C (annealing temperature depends on primers used) for 35 s, 72 C for 30 s, and 72 C for 5 min for final extension.Successful amplification was checked via electrophoresis on an agarose gel.PCR product was analyzed for single-nucleotide polymorphism using pyrosequencing (Qiagen, Hilden, Germany) according to the manufacturer's instructions (Keshtkar et al. 2015).

Effect of Malathion on Resistance to Mesosulfuron-Methyl þ Iodosulfuron-Methyl and Pyroxsulam
To assess the presence of NTSR caused by enhanced metabolism, plants of POAAN-R and POAAN-S populations at GS 12-13 were sprayed with ALS inhibitor mesosulfuronmethyl þ iodosulfuron-methyl or pyroxsulam at the recommended field rate (15 þ 5 g ha −1 or 18.8 g ha −1 ) and 1.5 of the recommended field rate (22.5 þ 7.5 g ha −1 or 28.1 g ha −1 ) with or without malathion at 1,000 g ai ha −1 .Malathion is an organophosphate insecticide known to inhibit P450-mediated metabolic resistance (e.g., Kaundun 2014;Yu and Powles 2014).Malathion was applied approximately 3 h before the application of ALS herbicides.Visual assessment for survival was conducted at 30 d after spraying.Each experiment consisted of three replicates, with or without malathion for each dose, and nontreated control for each population and was repeated.

Statistical Analysis
Data analyses were performed in R v. 3.6.3(R Core Team 2020).As ANOVA revealed no significant (P > 0.05) difference between the two experimental runs, survival data from single-dose assays were pooled for analysis, as were the shoot weight data from dose-response assays.Dose-response models were fit to the shoot fresh weight data using the DRC package (Ritz et al. 2015).Lack-of-fit F-tests were performed to assess model fit (P > 0.05).A three-parameter log-logistic model was selected to fit shoot weight data of both ALS-inhibiting herbicides, while a fourparameter Weibull-1 model was used to fit clethodim and glyphosate shoot weight data.As residuals were normally distributed, data were not transformed.Fitted models estimated the growth rate GR 50 (i.e., the effective dose rate required to obtain a growth reduction of 50% relative to untreated plants).The resistance index (RI) was calculated as GR 50 of POAAN-R divided by GR 50 of POAAN-S.

Resistance Mechanisms of Poa annua to ALS Herbicides
Single-dose assay results indicated that POAAN-R had 100% plants surviving (or no mortality recorded) when treated with field recommended rates of mesosulfuron-methyl þ iodosulfuronmethyl (15 þ 5 g ha −1 ) and of pyroxsulam (18.8 g ha −1 ) (Table 1).In contrast, POAAN-S was totally controlled by both of these herbicides at recommended rates.In the dose-response assays, shoot fresh weights recorded immediately after harvest were used  S2).TSR analysis by pyrosequencing confirmed that all plants from POAAN-R had a Trp-574-Leu (heterozygous) mutation of the ALS protein, which corresponded to the high levels of resistance to mesosulfuron-methyl þ iodosulfuron-methyl and pyroxsulam.No ALS Pro-197 mutation was detected in POAAN-R.As expected, there were no mutations found either at Pro-197 or Trp-574 in POAAN-S, which corresponded to its high sensitivity to both ALS herbicides.The application of the P450 inhibitor, malathion, followed by mesosulfuron-methyl þ iodosulfuronmethyl or pyroxsulam did not reverse resistance in POAAN-R, with 100% plants surviving (or no mortality recorded) at both rates 15 þ 5 g ha −1 or 18.8 g ha −1 (recommended field rate) and 22.5 þ 7.5 g ha −1 or 28.1 g ha −1 (1.5 of field recommended rate) (Supplementary Figures S3 and S4).
Repeated use of herbicides with the same mode of action can lead to weed resistance development (Yu and Powles 2014).To date, 171 weed species are reported to have developed resistance to ALS-inhibiting herbicide modes of action, the most for any herbicide group (Heap 2023).Resistance to ALS-inhibiting herbicides in different species is mostly caused by at least one of nine mutations at positions associated with ALS (Pro-197, Asp-376, Trp-574, Ala-122, Ala-205, Gly-654, Arg-377, Ser-653, and Phe-206) (Brosnan et al. 2016;Fang et al. 2022;Tranel et al. 2022).In our study, Trp-574-Leu mutations in POAAN-R were associated with resistance to two different chemistries of ALS inhibitors, with stronger resistance to mesosulfuron-methyl þ iodosulfuron-methyl than to pyroxsulam (Table 2).In nonagricultural crop situations, where resistant P. annua is prevalent, Trp-574 is the most common mutation conferring resistance to multiple ALS inhibitors (e.g., Brosnan et al. 2016;Cross et al. 2015;McElroy et al. 2013).Enhanced metabolism caused by low herbicide dose use can potentially cause NTSR to postemergence herbicides in several grass-weed species (e.g., Kaundun 2014;Torra et al. 2021;Yu and Powles 2014).However, similar levels of resistance in POAAN-R with or without the P450 inhibitor malathion treatment in our study suggest that NTSR by enhanced  Weed Science metabolism may be less likely to be the cause of resistance to mesosulfuron-methyl þ iodosulfuron-methyl or pyroxsulam.These results reiterate that the effects of low herbicide dose selection could be influenced by modes of action and species biology (mating system, ploidy levels, etc.), as well as standing genetic variation (i.e., the presence of different genetic alleles in a population) (e.g., Busi et al. 2013;Davies et al. 2018;Renton et al. 2011).

Susceptibility and Resistance of Poa annua to Other Herbicides
Single-dose assay results indicated that both POAAN-R and POAAN-S populations responded similarly, sensitive (i.e., all treated plants died) to clethodim, glyphosate, pendimethalin, and flufenacet herbicides at field recommended rates, but resistant (100% survivors) to propaquizafop and pinoxaden (Table 1).Dose-response assays confirmed that POAAN-R was equally susceptible to POAAN-S to both clethodim and glyphosate (Figure 2A and 2B), with GR 50 values of 24.8 g ha −1 and 17.4 g ha −1 or 104.2 g ha −1 and 84.6 g ha −1 , respectively, much lower than the recommended rate of 120 g clethodim ha −1 or 540 g glyphosate ha −1 , with very low RI (Table 3).Pyrosequencing TSR analysis revealed that the inheritance mutation of Ile-1781-Leu (heterozygous) in ACCase protein has been consistently detected in R and S. On the other hand, the mutations in other positions of ACCase proteins were not detected in both populations.No mutation of the EPSPS gene was detected in R and S, which coincided with their susceptibility to glyphosate at the field recommended rate.
The mutant Ile-1781 found in this study, has been frequently identified in several grass weeds with ACCase TSR (Hull et al. 2014;Kaundun 2014;Yu et al. 2007) but allotetraploid P. annua exhibits a natural tolerance to ACCase-inhibiting herbicides, due to a fixed Leu residue at Ile-1781 that results in an insensitive form of ACCase (Délye and Michel 2005;Ghanizadeh et al. 2020).Despite this naturally inherited trait, clethodim and haloxyfop are two ACCase herbicides that provide effective control of P. annua (Ghanizadeh et al. 2020).In fact, Délye and Michel (2005) and Barua et al. (2020) found P. annua resistance to propaquizafop or was due to mutant Ile-1781.Recently, Ghanizadeh et al. (2020) found haloxyfop-resistant P. annua caused by an ACCase Ile-2041 mutant.Consistent with this information, both POAAN-R and POAAN-S had a Ile-1781-Leu mutation in the ACCase protein.Furthermore, both R and S were sensitive to clethodim (Figure 2A; Table 3), which has never been used previously in that field, while being resistant to propaquizafop (used previously) and pinoxaden (never been used previously) (Table 1), which is also consistent with the common response to the ACCase-inhibiting herbicides in P. annua.Collectively, our results indicate that predominately heterozygous plants carrying the Ile-1781 mutation are sufficient to affect the sensitivity of specific ACCase-inhibiting herbicides, including propaquizafop and pinoxaden, but not clethodim.It is noteworthy that P. annua exhibits a distinct resistance spectrum, specifically, to ACCase graminicides, despite having the same mutation (Ile-1781) that is known to confer resistance to clethodim in other grass species (Délye et al. 2008;Yu et al. 2007).Even though the effectiveness of clethodim in controlling grass weeds with a high degree of ACCase mutation has been well documented (Moss et al. 2012;Yu et al. 2007), clethodim is not preferentially used by Irish growers (Alwarnaidu Vijayarajan et al. 2021) over the ACCase graminicides propaquizafop and cycloxydim.This is mainly due to the broad range of grass-weed activity of propaquizafop and cycloxydim, their cost-effectiveness, and their possibility to be used in both canola and bean crops.
In this region, P. annua is often considered a lower priority weed in most years and is not thought to have a large economic impact as a grass-weed of cereal crops, as it has been easy to control (Vijayarajan et al. 2022), but resistance evolution in P. annua may pose a future threat.In the study field where POAAN-R was sampled, crop production may not be sustainable.The deep noninversion tillage-based continuous winter cropping and poor management, often associated with: (1) deliberately using glyphosate at suboptimal rates, (2) not selecting suitable residual herbicides or using only narrow-spectrum and suboptimal timings (as early postemergence rather than preemergence), and (3) the selection pressure imposed by the continuous use of the broadspectrum herbicide mesosulfuron-methyl þ iodosulfuron-methyl (frequently at lower rates), could have reduced herbicide efficacy against POAAN-R and unintentionally selected for resistance to ALS inhibitors.Our study also confirmed the susceptibility of ALSresistant POAAN-R to other herbicides when applied at a field recommended rate, including burndown glyphosate, postemergence clethodim, and the preemergence residual herbicides pendimethalin and flufenacet.Therefore, there is an opportunity to use these options in conjunction with other cultural/ nonchemical tools to effectively eliminate or control POAAN-R.For the study field, methods to reduce seed return and deplete the soil weed seedbank should be implemented, such as: multiyear spring cropping or spring-based rotations (as these weeds thrive following autumn germination); inclusion of winter canola allowing the use of preemergence metazachlor (Group 15) to control POAAN-R, or use of early postemergence propyzamide (Group 3) and postemergence clethodim (as a follow-up option) to additionally control B. sterilis; use of glyphosate as a part of a stale seedbed technique; strategic plow-based tillage; spraying-off distinct weed patches; adopting strict machinery hygiene; and finally, establishment of perennial grass-based mixtures [e.g., orchardgrass (Dactylis glomerata L.) and timothy (Phleum pratense L.)] at the field margin Table 2. Shoot fresh weight GR 50 values (SEs in parentheses) of sensitive (POAAN-S) and resistant (POAAN-R) populations of Poa annua treated with a range of recommended field rates (±) of mesosulfuron-methyl þ iodosulfuronmethyl (15 þ 5 g ai ha −1 ) and pyroxsulam (18.8 g ai ha −1 ).  as part of wider strategy to prevent the encroachment of these weeds from the headland.In summary, our study is the first report to characterize the nature of recorded herbicide resistance to inhibitors mesosulfuronmethyl þ iodosulfuron-methyl and pyroxsulam in a P. annua, caused by the Trp-574 mutation, from an arable field.It is only the second such mesosulfuron-methyl þ iodosulfuron-methyl-resistant case reported, globally, in a cereal crop.Grass-weed challenges are increasing in Ireland (Vijayarajan et al. 2022), contributed to by use of cereal-dominated rotations, earlier autumn sowing and noninversion tillage adoption, herbicides used alone without supplementary weed control methods, use of lower than field recommended rates of postemergence ACCase/ALS-inhibiting herbicides, and new weed introductions.Because of these challenges, coupled with potential EU legislation change on plant protection products, more effort needs to be devoted to encourage proactive adoption of a total IWM approach.In this regard, this research conveys a message to growers and industry on the importance of crop and herbicide diversification, selecting suitable herbicides, correct application timing, and correct herbicide rates for maximum efficacy.These strategies in combination with cultural/nonchemical control practices will minimize or delay resistance evolution in target and non-target species as well as promoting reduced reliance on herbicides, or preserving the efficacy of existing effective herbicides, for weed control.