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Growth, fecundity, and competition between aryloxyphenoxypropionate-resistant and -susceptible Asia Minor bluegrass (Polypogon fugax)

Published online by Cambridge University Press:  29 July 2019

Wei Tang Open the ORCID record for Wei Tang [Opens in a new window] ,
Jie Chen ,
Xiaoyue Yu ,
Jianping Zhang  and
Yongliang Lu
Wei Tang
Affiliation:
Associate Professor, State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou, China
Jie Chen
Affiliation:
Professor, School of Forestry and Bio-technology, Zhejiang A&F University, Hangzhou, China
Xiaoyue Yu
Affiliation:
Associate Professor, State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou, China
Jianping Zhang
Affiliation:
Associate Professor, State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou, China
Yongliang Lu*
Affiliation:
Professor, State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou, China
*
Author for correspondence: Yongliang Lu, China National Rice Research Institute, No. 28 Shuidaosuo Road., Fuyang District, Hangzhou 311400, China. Email: luyongliang@caas.cn
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Abstract

Asia Minor bluegrass (Polypogon fugax Nees ex Steud.) is a problem grass weed of winter crops in China, where a population has become resistant to aryloxyphenoxypropionate (APP) herbicides. The mechanism of resistance is due to an Ile-2041-Asn mutation of the ACCase gene. Screen house experiments were conducted to study the growth, fecundity characteristics, and competitive ability of this aryloxyphenoxypropionate-resistant (APP-R) biotype compared with a susceptible (APP-S) biotype. When grown under noncompetitive conditions, the APP-R P. fugax developed more rapidly than the APP-S plants, with earlier tiller and panicle emergence and seed shedding; the APP-R P. fugax set seeds nearly 12 d earlier than the APP-S biotype. APP-R and APP-S biotypes had similar aboveground dry weight before the flowering stage. Fecundity of the APP-R biotype was similar to the APP-S biotype (8.57 g seeds plant−1 and 0.17 g seeds panicle−1 versus 8.22 g seeds plant−1 and 0.13 g seeds panicle−1, respectively). Ultimately, the relatively slower-developing APP-S P. fugax had 50% more shoot dry weight than the APP-R plants. Relative competitiveness among the APP-R and APP-S P. fugax biotypes was investigated through replacement series experiments. No difference in competitive ability was measured between APP-R and APP-S biotypes on the basis of shoot dry weight before the tillering stage. These results indicate that there is no apparent fitness penalty for the APP-R P. fugax. The shorter growth cycle of APP-R with no apparent fitness penalty suggests that growers will need begin weed control earlier and possibly include vegetative crops with an even shorter growth cycle in their rotations.

Keywords

Steven S. Seefeldt, Washington State UniversityACCase mutationfitnessherbicide resistancerelative competitiveness.
Type
Research Article
Information
Weed Science , Volume 67 , Issue 5 , September 2019 , pp. 546 - 551
Copyright
© Weed Science Society of America, 2019 

Introduction

Asia Minor bluegrass (Polypogon fugax Nees ex Steud.) is one of the most troublesome annual grass weeds in winter crops in China, affecting wheat (Triticum aestivum L.), oilseed rape (Brassica napus L.), and vegetable nurseries. This weed usually grows in damp lowlands or riparian areas and is also commonly found along field margins, roadsides, canal banks, and non-croplands. It generally emerges from September to October; flowering begins in early April, with seed dispersal occurring in May to June (Li Reference Li1998; Xu et al. Reference Xu, Qi, Lu, Yang and Xie2014). Polypogon fugax is adapted to a wide range of soil environments and has increasingly become a prevalent and important weed in many regions of China (He et al. Reference He, Lu, Ye, Zhang, Jiang, Feng, Zeng and Su2009; Zhang et al. Reference Zhang, Ma and Qiang2012; Zhu et al. Reference Zhu, Wei and Zhang2008), with serious impacts on agricultural production. It has been reported that this weed can reduce wheat yield by up to 40% (Zhang Reference Zhang1993).

Aryloxyphenoxypropionate herbicides (APPs) inhibit acetyl co-enzyme A carboxylase (ACCase), a key enzyme involved in fatty-acid biosynthesis (Focke et al. Reference Focke, Gieringer, Schwan, Jänsch, Binder and Braun2003; Gornicki et al. Reference Gornicki, Podkowinski, Scappino, DiMaio, Ward and Haselkorn1994). In recent decades, grass weeds such as Japanese foxtail (Alopecurus japonicus Steud.) and American sloughgrass [Beckmannia syzigachne (Steud.) Fernald] had been successfully controlled by POST application of APPs. The excellent control efficacy of these herbicides for many grass weed species (>90%) encouraged their widespread and repeated use. However, the frequent use of these herbicides has resulted in selection for herbicide resistance in many weed species, with resistance to these herbicides confirmed in 48 grass weeds worldwide and 8 grass weed species in China (Heap Reference Heap2018). Resistance to APPs is most commonly conferred by a target-site mutation in the ACCase gene, subsequently creating an altered amino acid sequence on the ACCase enzyme (Powles and Yu Reference Powles and Yu2010). We have recently identified a P. fugax biotype from Qingshen County in Sichuan Province with 8- to 1,991-fold resistance to five different APP herbicides. The resistance mechanism of this biotype was a single amino acid substitution in the plastid ACCase, Ile-2041-Asn (Tang et al. Reference Tang, Zhou, Chen and Zhou2014).

Herbicide resistance may or may not confer fitness penalties in the resistant populations. Development of effective management strategies for herbicide-resistant weeds requires an understanding of the resistance-endowing mechanism and its potential fitness variation. Previous studies have determined that different mutations in the ACCase gene conferred varied pleiotropic effects along with ACCase-inhibitor resistance. For instance, plants segregating for Ile-1781-Leu mutation exhibited similar relative growth rate, biomass accumulation, and seed production compared with susceptible plants for smooth barley [Hordeum murinum L. ssp. glaucum (Steud.) Tzvelev], blackgrass (Alopecurus myosuroides Huds.), and rigid ryegrass (Lolium rigidum Gaudin) in the absence of herbicide selection (Menchari et al. Reference Menchari, Chauvel, Darmency and Délye2008; Shergill et al. Reference Shergill, Boutsalis, Preston and Gill2016; Vila-Aiub et al. Reference Vila-Aiub, Neve, Steadman and Powles2005). Green foxtail [Setaria viridis (L.) P. Beauv] plants with the Ile-1781-Leu mutation had greater fitness than susceptible plants when grown in the greenhouse or in the field (Wang et al. Reference Wang, Picard, Tian and Darmency2010). However, A. myosuroides plants containing the Asp-2078-Gly mutation and L. rigidum plants with the Asp-2078-Gly or the Cys-2088-Arg mutation exhibited a fitness cost (Menchari et al. Reference Menchari, Chauvel, Darmency and Délye2008; Vila-Aiub et al. Reference Vila-Aiub, Neve and Powles2009).

It has been acknowledged that biotypes with similar genetic backgrounds should be involved for the quantification of fitness cost with the resistance genes (Délye et al. Reference Délye, Jasieniuk and Le Corre2015). Here we only detected one aryloxyphenoxypropionate-resistant (APP-R) biotype of P. fugax; to minimize differences in environmental factors, a susceptible (APP-S) biotype was collected from adjacent areas of the same field with similar growing conditions, and then F2 seeds of the two biotypes grown in the greenhouse under the same conditions were used in this study. A previous study indicated that the APP-S biotype had increased germination and emergence rates compared with the APP-R biotype (Tang et al. Reference Tang, Xu, Shen and Chen2015). The main objective of the present research was to determine (1) the growth and fecundity of the APP-R and APP-S biotypes (2) and their competitive ability in replacement series experiments in the absence of APP herbicide application. This information will increase our understanding of the potential fitness differences between the APP-R and APP-S biotypes and could be helpful for the overall development of resistance management strategies.

Material and Methods

Plant Material

Polypogon fugax seeds were originally collected in 2012 from APP-R and APP-S plants found in or nearby a grower’s field in Qingshen County, Sichuan Province, China (Tang et al. Reference Tang, Xu, Shen and Chen2015). The APP-R and APP-S P. fugax biotypes were separately cultivated in a screen house (an 8 m by 20 m chamber framed with 2-cm iron mesh and covered overhead with a transparent plastic cover to prevent rain damage) for 2 yr at the China National Rice Research Institute (CNRRI; 30.04°N, 119.55°E), Hangzhou, Zhejiang Province, China. A whole-plant dose–response experiment was conducted to confirm the resistance level of the F2 plants of APP-R P. fugax in the CNRRI screen house. At the 3-leaf stage, the APP-R biotype survived a clodinafop-propargyl application rate of 48 g ai ha−1, whereas, the APP-S biotype was completely controlled. The F2 plants of the APP-R biotype were 1,965-fold more resistant to clodinafop-propargyl compared with the F2 plants of the APP-S biotype (data not shown). Seeds collected from F2 plants of the two biotypes in May 2014 were used in this study. The collected seeds were air-dried in the shade for 10 d, then cleaned and stored in paper bags at 4 C until being conditioned for experiments. Seed germination rates were close to 95% and 75% in a preliminary experiment in the incubator (15/5 C fluctuating day/night temperatures, 12-h light/12-h dark) for the APP-R and APP-S biotypes, respectively (data not shown).

Noncompetitive Growth and Seed Production

A screen house experiment was conducted at the CNRRI. Seeds of each biotype (APP-R and APP-S) were sown in plastic trays (24 cm by 18 cm by 5 cm) containing a potting medium (1:1:1:2 vegetable garden soil/compost/peat/dolomite) with pH 6.3 and 13.7% organic matter. Plants were grown in a screen house with average day/night temperatures of 20/10 C under natural light (average intensity of 700 mmol m−2 s−1). Seeds were planted on November 9, 2015, and November 12, 2016. The trays were watered every 48 h. After emergence, seedlings at the 1-leaf stage were transplanted to plastic pots (12-cm diameter, 10-cm height) containing the same medium described earlier. The seedlings were transplanted on November 19, 2015, and November 23, 2016, respectively. Each pot contained a single APP-R or APP-S P. fugax seedling. Pots were placed in a completely randomized design with 120 pots for each biotype. No supplemental fertilizer was applied, and plants were periodically rotated on the bench to minimize environmental variation. For growth rate studies, four randomly selected plants of each biotype were harvested weekly for 15 consecutive weeks beginning 3 wk after transplant. The plants were clipped at the soil surface, bagged, and dried at 70 C for 72 h. The dry weight of each sample was measured.

Twelve plants of each biotype were retained for reproductive studies. The number of days after transplant (DAT) was recorded for the initial visible appearance of a developing tiller, flower, and inflorescence. After flowering, each panicle was gently enclosed in a pollination bag for seed collection. The seeds reaching physiological maturity (characterized by yellow seed color) were harvested from each plant and then dried in the shade for 1 wk. Seeds were separated manually and cleaned, and seed yield was measured as grams of seed per plant, and the number of panicles per plant and grams of seed per panicle were calculated. Aboveground biomass of each plant was also recorded as described for the growth rate experiment.

Competitive Growth Study

The relative competitive ability of the APP-R and APP-S biotypes was also compared under the aforementioned screen house conditions in November 2014 and 2015. A replacement series experiment was conducted at the CNRRI using a completely randomized design with four replicates in November 2014. This experiment was repeated in December 2015. Polypogon fugax seedlings were transplanted into plastic pots (25-cm diameter, 15-cm height) and equally distributed in 2 by 2, 3 by 3, or 4 by 4 grids (Jolliffe Reference Jolliffe2000; Shrestha et al. Reference Shrestha, Hanson, Fidelibus and Alcorta2010) to achieve final densities of 4, 9, and 16 plants pot−1, or 82, 184, and 327 plants m−2. These levels of P. fugax infestation are not uncommon in wheat or oilseed rape fields in south China. Five biotype proportions (100:0, 75:25, 50:50, 25:75, and 0:100) were used at each density level, and each individual APP-R and APP-S P. fugax plant was marked with a plastic stake to ensure proper identification throughout the experiment. In the 9 plants pot−1 density, planting ratios were based on 8 plants and and an APP-R or APP-S P. fugax plant was randomly assigned as the 9th plant to complete the planting grid. Plants were cut at the soil surface at 90 DAT before panicles appeared, dried at 70 C for 72 h, and weighed for shoot dry weight. Individual plant shoot dry weight data were subjected to ANOVA.

Statistical Analysis

A completely randomized design was used in all experiments, and each experiment was repeated once. Data obtained from screen house experiments were tested for normality, and ANOVA was performed using SPSS software (v. 13.0; SPSS, Chicago, IL). No interactions (P > 0.05) occurred between year and biotype for any of the parameters. Therefore, data from the two experimental repetitions were pooled. Mean comparison was performed using Student’s t test, and the overall differences were significant (P = 0.05).

For growth rate studies, shoot dry weight (W) at time T was fit using the following four-parameter log-logistic equation:

([1]) $$W = {A_{\rm{2}}} + {{{A_{\rm{1}}} - {A_{\rm{2}}}} \over {{\rm{1}} + {\rm{exp}}\ \{b\left[ {{\rm{log}}\left( x \right)} \right] - {\rm{log}}{T_{50}\}}}}$$

where A 2 = the lower limit, A 1 = the upper limit, b = the slope at the T 50, and T 50 is the DAT when W is 50% of the maximum.

Results and Discussion

Noncompetitive Growth and Phenological Development

Phenologically, the APP-R and APP-S P. fugax biotypes were similar, with no distinguishing characteristics between them before panicle emergence. The relationship between P. fugax plant biomass and establishment time was described by a logistic regression model (Figure 1). Aboveground dry shoot biomass of APP-R and APP-S P. fugax was similar at each harvest (21 to 112 DAT), and no difference (P>0.05) in average dry shoot biomass was detected at 120 DAT until the emergence of panicles. This result is in agreement with an Ile-2041-Asn A. myosuroides biotype, for which no differences in vegetative biomass were determined (Menchari et al. Reference Menchari, Chauvel, Darmency and Délye2008). Similar results were also reported in several other grass weed species segregating for Ile-1781-Leu mutation (Menchari et al. Reference Menchari, Chauvel, Darmency and Délye2008; Shergill et al. Reference Shergill, Boutsalis, Preston and Gill2016; Vila-Aiub et al. Reference Vila-Aiub, Neve, Steadman and Powles2005). The slightly reduced dry biomass produced by the APP-R plants during the vegetative growth phase could be partly related to the moderately reduced ACCase enzyme activity reported in A. myosuroides (Délye et al. Reference Délye, Zhang, Chalopin, Michel and Powles2003).

Figure 1. Aboveground shoot dry biomass of aryloxyphenoxypropanoate-resistant (APP-R) and aryloxyphenoxypropanoate-susceptible (APP-S) Polypogon fugax biotypes grown under noncompetitive conditions. Vertical bars represent SEs. The line represents a four-parameter sigmoid model, W = A 2 + (A 1 − A 2)/(1+ x/T 50)^p, fit to the data, where A 2 = the lower limit, A 1 = the upper limit, p = the slope at the T 50, and T 50 is the days after transplant when W is 50% of the maximum.

The APP-R biotype exhibited accelerated phenological development compared with the APP-S biotype under noncompetitive conditions (Table 1). The APP-R P. fugax reached tiller and panicle emergence and seed-shedding stages earlier than the APP-S biotype. The average time for these stages was 15, 121, and 143 d, respectively, for the APP-R biotype, which was about 6, 10, and 12 d, respectively, earlier than the APP-S biotype. Similar phenomena were reported in a H. murinum biotype containing the Ile-2041-Asn mutation, for which the date of panicle emergence was 20 d earlier than for the susceptible biotype (Shergill et al., Reference Shergill, Boutsalis, Preston and Gill2016). Wang et al. (Reference Wang, Picard, Tian and Darmency2010) determined that Setaria spp. mutants segregating the ACCase 1781 allele flowered earlier, and they were shorter at maturity than the susceptible plants. These differences in plant growth may affect control practices based simply on crop growth stage. The APP-R plants may be at a more advanced growth stage of phenological development than the APP-S biotype at the time of POST herbicide application, or the advanced APP-R plants maybe already dropping seeds by the time hand weeding is conducted (when panicles of most weeds emerged). Therefore, differences in plant phenology need to be taken into consideration when developing APP-R P. fugax management strategies.

Table 1. Time for aryloxyphenoxypropanoate–resistant (APP-R) and aryloxyphenoxypropanoate–susceptible (APP-S) Polypogon fugax biotypes grown in a screen house to reach different phenological stages in terms of days after transplant (DAT) a

a Data were averaged over 2 yr. SEs are in parentheses. Means within a column for biotype followed by the same letter are not different according to Student’s t test at P = 0.05.

Inflorescence Characteristics and Seed Production

The beginning of inflorescence development can be identified by the elongation of the shoot meristem as it undergoes the transition from vegetative to reproductive growth. The inflorescence shape of the APP-R and APP-S biotypes at the panicle emergence stage were similar; however, obvious and noticeable differences appeared as the inflorescence expanded. All panicles of the APP-S biotype appeared very open, with relatively loose branches (Figure 2). In contrast, the shape of the panicle of the APP-R plants was more compact, and the branches appeared close to the rachis during flowering.

Figure 2. Inflorescence characteristics of aryloxyphenoxypropanoate-resistant (APP-R, top row) and aryloxyphenoxypropanoate-susceptible (APP-S, bottom row) Polypogon fugax biotypes. (1) Panicle emergence stage; (2) inflorescence expansion stage; (3) inflorescence fully expanded; (4) seed maturity stage.

The ACCase Ile-2041-Asn substitution has been observed in other grass weed species (Scarabel et al. Reference Scarabel, Panozzo, Varotto and Sattin2011; Tang et al. Reference Tang, Li, Dong, Dong, Lü and Zhu2012; Yu et al. Reference Yu, Collavo, Zheng, Owen, Sattin and Powles2007). There has, however, been no report of any inflorescence variation linked with this mutation in these species. Morphological and structural alternations associated with target site–resistant biotypes have been reported in some weed species (Nandula et al. Reference Nandula, Poston, Koger, Reddy and Reddy2015; Tardif et al. Reference Tardif, Rajcan and Costea2006). To eliminate the possibility of the APP-R and APP-S biotypes belonging to different species, we carried out multigene approaches that use combinations of variable noncoding and relatively conserved coding regions of the plastid genome (Burgess et al. Reference Burgess, Fazekas, Kesanakurti, Graham, Husband, Newmaster, Percy, Hajibabaei and Barrett2011; Yu et al. Reference Yu, Ji, Emerson, Wang, Ye, Yang and Ding2012). Results indicated that there were no differences in nuclear ribosomal internal transcribed spacer region (ITS; GenBank accessions KP135427 and KP135428 for APP-R and APP-S P. fugax, respectively) and rbcL (GenBank accessions KP135425 and KP135426) and matK (GenBank accessions KP135423 and KP135424) coding regions of the two biotypes (data not shown). These results indicated that both APP-R and APP-S biotypes belong to P. fugax.

The link between the altered ACCase enzyme caused by the Ile-2041-Asn substitution and the inflorescence variation observed in the APP-R biotypes is not clear. In our previous study, we analyzed the transcriptomes of the APP-R biotype and a susceptible biotype of P. fugax and found 12 unigenes were differentially expressed at the early flowering stage, which provides a genomic resource for understanding the molecular basis of early flowering (Zhou et al. Reference Zhou, Zhang, Tang, Wang and Gao2017). Whether this mutation has such a large impact in other species, and what eventual link this would have with the morphological variation that we have observed, would be worth examining.

The aboveground biomass and the number of panicles per plant were lower in the APP-R biotype (54.8 panicles plant −1) compared with the APP-S biotype (64.0 panicles plant −1) under noncompetitive conditions (Table 2); however, the APP-R biotype produced greater weight of seeds per panicle than the APP-S biotype (0.1664 vs. 0.1313 g seeds panicle −1, respectively). The APP-R biotype had relatively greater 1,000-seed weight (150 vs. 145 mg) than the APP-S biotype (Tang et al. Reference Tang, Xu, Shen and Chen2015); fewer panicles with greater weight resulted in no significant differences in seed production among the APP-R and APP-S biotypes. This trend indicates that the fecundity is not related to the ACCase resistance trait. These results are in agreement with a previous report that determined no differences in seed production between the Ile-2041-Asn ACCase A. myosuroides and susceptible plants (Menchari et al. Reference Menchari, Chauvel, Darmency and Délye2008). Also, seed production and weight levels were found to be the same in ACCase inhibitor–resistant and ACCase inhibitor–susceptible sterile oat (Avena sterilis L.), H. murinum, and L. rigidum (Shergill et al. Reference Shergill, Boutsalis, Preston and Gill2016; Travlos Reference Travlos2013; Vila-Aiub et al. Reference Vila-Aiub, Neve, Steadman and Powles2005).

Table 2. Seed production for aryloxyphenoxypropanoate–resistant (APP-R) and aryloxyphenoxypropanoate–susceptible (APP-S) Polypogon fugax biotypes under noncompetitive conditions a

a Data were averaged over 2 yr.SEs are in parentheses. Means within a column for biotype followed by the same letter are not different according to Student’s t test at P = 0.05.

Frequency distributions of seed weights per panicle for APP-R and APP-S biotypes of P. fugax were also determined (Figure 3). The APP-R biotype developed more high-yield panicles (more total seed weight per panicle), with 7.6%, 6.2%, and 2.6% panicles, respectively, at the panicle weight increments of 0.3 to 0.4 g, 0.4 to 0.5 g, and >0.5 g, respectively, compared with 5.0%, 0.3%, and 0%, respectively, for the APP-S biotype. This resulted in similar seed production per plant, and there were no differences among the APP-R and APP-S biotypes regarding their total seed mass per plant (P > 0.05). However, the aboveground shoot dry weight (11.6 vs. 22.4 g plant −1, respectively) after seed harvest was different between the APP-R and APP-S biotypes (P < 0.05). This may be attributed to physiological differences resulting in a more efficient transformation of the resources available for flowering and seed production for the APP-R biotype (Bourdôt et al. Reference Bourdôt, Saville and Hurrell1996; Kumar and Jha Reference Kumar and Jha2016).

Figure 3. Panicle weight increments of aryloxyphenoxypropanoate-resistant (APP-R) and aryloxyphenoxypropanoate-susceptible (APP-S) Polypogon fugax biotypes seedlings. Vertical bars represent SEs.

Competitive Study

When the APP-R and APP-S biotypes were grown in mixtures under competitive conditions, the aboveground shoot dry weight before tiller emergence of the APP-R biotype plants was similar to that of the APP-S biotype (P > 0.05) and in general terms corresponded to the theoretical response of two biotypes having equal competitive ability (Figure 4). At the three tested densities, individual shoot dry weights of APP-R and APP-S biotypes were similar in monoculture and were not different in any proportions of mixture. This implies that there is no apparent competitive disadvantage for this particular APP-R biotype, and the APP-R plants are likely to persist in the population when the use of ACCase-inhibiting herbicide is discontinued. Similar results have been reported in ACCase inhibitor–resistant and ACCase inhibitor–susceptible giant foxtail (Setaria faberi Herrm.), L. rigidum, and A. sterilis (Gill et al. Reference Gill, Cousens and Allan1996; Travlos Reference Travlos2013; Wiederholt and Stoltenberg Reference Wiederholt and Stoltenberg1996), but the ACCase-resistance mechanism was unknown in these studies. Studies with the Ile-1781-Leu mutation inL. rigidum and A. myosuroides also indicated no differences in competitive abilities compared with the susceptible biotypes (Menchari et al. Reference Menchari, Chauvel, Darmency and Délye2008; Vila-Aiub et al. Reference Vila-Aiub, Neve, Steadman and Powles2005).

Figure 4. Replacement series diagrams for plant biomass of aryloxyphenoxypropanoate-resistant (APP-R) and aryloxyphenoxypropanoate-susceptible (APP-S) Polypogon fugax biotypes of 4 (A), 9 (B), and 16 (C) plants pot−1 densities grown under competitive conditions at different proportions. Vertical bars represent SEs. Dotted lines represent the expected hypothetical values for two equally competitive biotypes.

The results of the current study revealed that the Ile-2041-Asn mutation had no negative effects on the fitness of APP-R P. fugax. In our previous study, seeds of the APP-R biotype had reduced germination and emergence percentage and a less adaptive range under same treatment conditions compared with the APP-S biotype (Tang et al. Reference Tang, Xu, Shen and Chen2015), indicating that the APP-R biotype may have stronger dormancy and a longer persistence period in the soil. These results also indicated that for a similar seedbank, APP-S P. fugax will emerge and be controlled with continued APP herbicide selection pressure, whereas the APP-R population will increase.

Finally, to assess fitness costs associated with mutant ACCase alleles, it is critical that the resistant and susceptible individuals share a similar genotype or that a group of plants having the same genotype be investigated (Cousens et al. Reference Cousens, Gill and Speijers1997; Strauss et al. Reference Strauss, Rudgers, Lau and Irwin2002; Vila Aiub et al. Reference Vila-Aiub, Neve and Powles2009). Although we collected several other accessions of P. fugax from different areas, no other resistant biotypes were found. The many panicles, desynchronous flowering, and self-crossing characteristic of P. fugax make crossing efforts unlikely. To unequivocally attribute fitness cost endowed by the ACCase-inhibiting herbicide resistance alleles, F2 populations from similar environments were used in this study. While impact of resistance on plant fitness can be altered by several factors (Warwick and Black Reference Warwick and Black1994), we did not measure any differences other than rate of maturity.

Author ORCIDs

Wei Tang, https://orcid.org/0000-0001-6372-1102.

Acknowledgments

The authors thank Xiaoyan Xu, Yanfei Yao, and Ruiping Wu for their technical assistance for part of this work and Hanwen Wu (NSW Department of Primary Industries, Australia) and Yufang Chen for their assistance in preparing graphs and revising the article. This work was financially supported by the Rice Pest Management Research Group of the Agricultural Science and Technology Innovation Program of China Academy of Agricultural Science, the China Agriculture Research System (CARS-01-02A). The authors declare no conflicts of interest.

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Figure 0

Figure 1. Aboveground shoot dry biomass of aryloxyphenoxypropanoate-resistant (APP-R) and aryloxyphenoxypropanoate-susceptible (APP-S) Polypogon fugax biotypes grown under noncompetitive conditions. Vertical bars represent SEs. The line represents a four-parameter sigmoid model, W = A2+ (A1− A2)/(1+ x/T50)^p, fit to the data, where A2 = the lower limit, A1 = the upper limit, p = the slope at the T50, and T50 is the days after transplant when W is 50% of the maximum.

Figure 1

Table 1. Time for aryloxyphenoxypropanoate–resistant (APP-R) and aryloxyphenoxypropanoate–susceptible (APP-S) Polypogon fugax biotypes grown in a screen house to reach different phenological stages in terms of days after transplant (DAT)a

Figure 2

Figure 2. Inflorescence characteristics of aryloxyphenoxypropanoate-resistant (APP-R, top row) and aryloxyphenoxypropanoate-susceptible (APP-S, bottom row) Polypogon fugax biotypes. (1) Panicle emergence stage; (2) inflorescence expansion stage; (3) inflorescence fully expanded; (4) seed maturity stage.

Figure 3

Table 2. Seed production for aryloxyphenoxypropanoate–resistant (APP-R) and aryloxyphenoxypropanoate–susceptible (APP-S) Polypogon fugax biotypes under noncompetitive conditionsa

Figure 4

Figure 3. Panicle weight increments of aryloxyphenoxypropanoate-resistant (APP-R) and aryloxyphenoxypropanoate-susceptible (APP-S) Polypogon fugax biotypes seedlings. Vertical bars represent SEs.

Figure 5

Figure 4. Replacement series diagrams for plant biomass of aryloxyphenoxypropanoate-resistant (APP-R) and aryloxyphenoxypropanoate-susceptible (APP-S) Polypogon fugax biotypes of 4 (A), 9 (B), and 16 (C) plants pot−1 densities grown under competitive conditions at different proportions. Vertical bars represent SEs. Dotted lines represent the expected hypothetical values for two equally competitive biotypes.