Glyphosate resistance in Palmer amaranth was first confirmed in North Carolina in 2005. A survey that year indicated 17 and 18% of 290 populations sampled were resistant to glyphosate and thifensulfuron, respectively. During the fall of 2010, 274 predetermined sites in North Carolina were surveyed to determine distribution of Palmer amaranth and to determine if and where resistance to fomesafen, glufosinate, glyphosate, and thifensulfuron occurred. Palmer amaranth was present at 134 sites. When mortality for each biotype was compared to a known susceptible biotype for each herbicide within a rate, 93 and 36% of biotypes were controlled less by glyphosate (840 g ae ha−1) and thifensulfuron (70 g ai ha−1), respectively. This approach may have underestimated resistance for segregating populations due to lack of homogeneity of the herbicide resistance trait and its contribution to error variance. When mortality and visible control were combined, 98% and 97% of the populations were resistant to glyphosate and the ALS inhibitor thifensulfuron, respectively, and 95% of the populations expressed multiple resistance to both herbicides. This study confirms that Palmer amaranth is commonly found across the major row crop production regions of North Carolina and that resistance to glyphosate and ALS-inhibiting herbicides is nearly universal. No resistance to fomesafen or glufosinate was observed.
1. Introduction
The majority of corn (Zea mays L.), cotton (Gossypium hirsutum L.), and soybean (Glycine max (L.) Merr.) in the United States is currently planted with glyphosate-resistant cultivars or hybrids [1]. Glyphosate has often been applied multiple times during a growing season and for several consecutive years with few other herbicides included [2–4]. This approach, while providing excellent weed control in cotton and soybean in most instances [5–8], has placed unprecedented selection pressure on weed communities and has contributed to a shift to more resistant biotypes [9].
Glyphosate resistance in Palmer amaranth was first confirmed in Georgia in 2005 [10] and later the same year in North Carolina [11, 12]. Levels of resistance varied by population in North Carolina, with some populations requiring over 20 times more glyphosate to reduce shoot fresh weight by 50% as compared with susceptible populations [12]. Glyphosate-resistant Palmer amaranth now occurs in Alabama, Arizona, Arkansas, Delaware, California, Georgia, Illinois, Louisiana, Michigan, Mississippi, Missouri, New Mexico, North Carolina, Ohio, South Carolina, Tennessee, and Virginia [13, 14].
Palmer amaranth is currently one of the most common and most troublesome weeds in many southern states due to its competitive nature and resistance to multiple herbicides [15, 16]. A survey was conducted in the fall of 2005 to determine the extent and distribution of glyphosate-resistant Palmer amaranth in North Carolina [12]. Resistance to glyphosate was observed in 17% of the 295 populations sampled. Additionally, resistance to thifensulfuron was observed in 18% of the populations.
It is generally accepted that glyphosate-resistant Palmer amaranth has become more common and more widespread since 2005. Determining how distribution of glyphosate-resistant Palmer amaranth has changed since 2005 and determining if resistance to other herbicides occurs are important in helping growers and those who advise growers develop effective management strategies to control this weed. Furthermore, understanding the extent and distribution of the problem is important for developing recommendations to curb the spread of glyphosate resistance to noninfested regions.
Fomesafen and glufosinate are used to control broadleaf weeds in major agronomic crops in the US and have become effective and widely used alternatives to glyphosate in these crops, especially when glyphosate-resistant weed biotypes are present [17–22]. There is concern that widespread and repeated use of these herbicides could lead to selection for resistance to the modes of action represented by fomesafen and glufosinate. To date, biotypes in North Carolina expressing resistance to these herbicides either do not exist or have not been under sufficient selection pressure to express resistance in fields in North Carolina. Determining if resistance to these herbicides exist will help growers and their advisors employ alternatives to glyphosate and if needed to control biotypes resistant to fomesafen and glufosinate if they occur. Therefore, objectives of this study were (1) to determine the distribution of glyphosate- and thifensulfuron-resistant biotypes of Palmer amaranth in North Carolina compared with the distribution in 2005 and (2) to determine if resistance to fomesafen and glufosinate is present in North Carolina Palmer amaranth populations.
2. Materials and Methods
A survey was administered across the Coastal Plain and Piedmont regions of North Carolina during the fall of 2010 using a grid sampling procedure. A map of the state (North Carolina DeLorme Atlas & Gazetteer, 9th edition, DeLorme Co., Yarmouth, ME) with latitude and longitude marked at increments of 0.1722 degrees and 0.2167 degrees, respectively, was used. Sample points were established at the intersection of each latitude and longitude marking (19.03 km by 19.8 km). Sample points falling within urban areas were omitted. A total of 274 predetermined sites were selected (Figure 1). Some sites were in forests, pastures, swamps, or residential areas, and no Palmer amaranth was present. If no Palmer amaranth was found at the predesignated site, an effort was made to survey surrounding areas within a 1.6-km radius.
Sample sites for the 2010 survey of North Carolina.
A total of 134 Palmer amaranth populations were sampled from soybean and cotton fields. Seed heads from 20 or more plants were collected per site and bulked in paper bags. Seed heads were air-dried and hand-threshed, and seeds were stored at 1°C until further use. Plants from seeds collected at these sites were grown in excess in a greenhouse in four replicate pots (7.5 by 12 cm by 5 cm) per herbicide rate using a commercial growing medium (Metro Mix 200, Scotts-Sierra Horticultural Products Company, Marysville, OH). Plants were thinned to four to five per pot 5 d after emergence. A known glyphosate-susceptible and a known glyphosate-resistant population were included for comparison in the experiment with glyphosate [12]. Each pot received 25 mL of a 4.6 g L−1 fertilizer solution (Peters Professional Water Soluble 20-20-20 Fertilizer, Scotts-Sierra Horticultural Products Co., Marysville, OH) 10 and 20 d after weed emergence. Pots were watered three times daily using automatic sprinklers. The greenhouse was maintained at 35±5°C, and natural lighting was supplemented for 14 h daily with metal halide lamps (Hubbell Lighting Inc., Greenville, SC) delivering 400 μmol m−2 s−1.
In separate experiments, Palmer amaranth 10–15 cm tall was treated with the potassium salt of glyphosate (Roundup WeatherMAX Herbicide, Monsanto Co., St. Louis, MO) at 0, 280, 560, and 840 g ae ha−1, glufosinate-ammonium (Ignite 280 Herbicide, Bayer CropScience, Research Triangle Park, NC) at 0, 410, 820, and 1230 g ae ha−1, the sodium salt of fomesafen (Reflex Herbicide, Syngenta Crop Protection, Greensboro, NC) at 0, 280, 560, and 840 g ae ha−1, and thifensulfuron-methyl (DuPont Harmony SG Herbicide, DuPont Crop Protection, Wilmington, DE) at 0, 4.37, 17.5, and 70 g ae ha−1. In previous research under similar greenhouse conditions, glyphosate and thifensulfuron at 280 and 4.37 g ha−1, respectively, were found to control glyphosate-susceptible and thifensulfuron-susceptible Palmer amaranth at least 95% [12]. In a preliminary experiment, glufosinate at 410 g ha−1 and fomesafen at 280 g ha−1 controlled Palmer amaranth at least 95%. The manufacturer’s suggested use rates for glyphosate, glufosinate, fomesafen, and thifensulfuron in soybean are 866, 450–594, 280–420, and 4.37 g ha−1, respectively [23–26]. Thifensulfuron was selected to represent herbicides that inhibit ALS because it is effective in controlling Palmer amaranth and was used previously by Whitaker [12] as an indicator herbicide in a survey similar to the one presented here. A nonionic surfactant (Induce adjuvant, Helena Chemical Co., Collierville, TN) at 0.25% (v/v) was included with fomesafen and thifensulfuron. Herbicides were applied using a CO2-pressurized backpack sprayer calibrated to deliver 145 L ha−1 at 275 kPa (glyphosate) or 187 L ha−1 at 375 kPa (fomesafen, glufosinate, and thifensulfuron) using regular flat-fan nozzles (TeeJet VisiFlo TP 11002 Flat Spray Tips, TeeJet Technologies, Wheaton, IL). Differences in spray volume were based on recommendations by the manufacturers and the goal of optimizing performance for each herbicide. The manufacturer of glyphosate recommends lower spray volumes [23] in part because glyphosate is systemic in plants. Fomesafen and glufosinate are considered contact herbicides with limited translocation. Higher spray volumes are recommended to ensure contact with adequate foliage to control weeds [24, 25]. Thifensulfuron can be applied in a range of spray volumes [26]. Percent visible control according to Frans et al. [27] and the number of surviving plants were recorded 14 d after fomesafen, glufosinate, and glyphosate application and 28 d after thifensulfuron application. Percent mortality relative to the nontreated control was calculated. Based on preliminary research, Palmer amaranth control by fomesafen, glufosinate, and glyphosate under greenhouse conditions is readily apparent 14 d after treatment. Control by thifensulfuron and other ALS-inhibiting herbicides can be slower, and a longer period of time after application is required to assess herbicide efficacy.
The experimental design in the greenhouse was a randomized complete block with four replications and the experiment was repeated once for each herbicide. Data for percent visible control and mortality were subjected to ANOVA by herbicide appropriate for the number of biotypes and herbicide rates excluding the nontreated control. Significance (P≤0.05) between biotypes and a known herbicide-susceptible biotype was determined using Dunnett’s Procedure in SAS (SAS v9.1, SAS Institute Inc., Cary, NC 27513, USA). Because variation from complete control or mortality to no control or survival was noted for individuals within many of the populations, Dunnett’s procedure most likely underestimated resistance due to lack of genetic homogeneity associated with herbicide resistance within populations contributing to relatively high error variance. Therefore, biotypes were grouped as susceptible, resistant, or highly resistant according to response to each herbicide and rate of each herbicide. Palmer amaranth was considered susceptible to the herbicides if control was 90% or greater and mortality 80% or greater at the low application rate, or if control was 95% or greater and mortality 90% or greater at the intermediate rate. Palmer amaranth was considered highly resistant if mortality was 30% or less at the high application rate. Populations meeting neither of the above criteria were categorized as resistant.
3. Results and Discussion
North Carolina is divided into three physiographic regions—the Mountain region in the western part of the state, the Piedmont Plateau in the central part, and the Coastal Plain in the eastern part [28]. In 2010, 78, 93, 100, 80, 74, and 72% of the state’s corn, cotton, peanut (Arachis hypogaea L.), soybean, tobacco (Nicotiana tabacum L.), and wheat (Triticum aestivum L.), respectively, were grown in the Coastal Plain while 19, 7, 0, 20, 23, and 27%, respectively, were grown in the Piedmont [29]. Only 3% of the corn and tobacco and 1% of the wheat were grown in the Mountain region. This survey, therefore, covered the major agronomic crop production areas of the state (Figure 1).
Palmer amaranth increased its geographical range within the state between 2005 and 2010. Compared to 2005, when Palmer amaranth was most commonly found in the central and southern Coastal Plain (Figure 2), the weed was more readily found in the far eastern and northeastern counties of the Coastal Plain and in the Piedmont in 2010 (Figure 3).
Distribution of Palmer amaranth in 2005 survey, adapted from Whitaker [12].
Distribution of glyphosate- and thifensulfuron-resistant Palmer amaranth in 2010.
When comparing the number of Palmer amaranth biotypes controlled at least 90%, increasing the rate of each herbicide increased the number of biotypes controlled (Table 1). However, no more than 8 Palmer amaranth biotypes were controlled by glyphosate at 840 g ha−1 while 70 biotypes were controlled by thifensulfuron at 70 g ha−1 (Table 1). One hundred twenty-six, or 94%, of Palmer amaranth biotypes were not controlled at least 90% by the highest rate of glyphosate (Table 1). For thifensulfuron, 64 biotypes, or 48%, of biotypes were not controlled by the highest rate of this herbicide (Table 1).
Number of Palmer amaranth biotypes controlled at least 90% by glyphosate and thifensulfuron and the number and percentage of Palmer amaranth biotypes not controlled by the highest rate of glyphosate and thifensulfuron.
Herbicide
Number of Palmer amaranth biotypes
Controlled 90% by each rate
Controlled less than 90% by the highest rate*
g ae ha−1
Glyphosate
280
560
840
126 (93)
3
4
8
g ae ha−1
Thifensulfuron
4.37
17.5
70.0
64 (48)
5
50
70
*Value in parenthesis represents the percentage of Palmer amaranth biotypes.
Mortality and visible control of 95 and 87% of biotypes, respectively, treated with glyphosate at 840 g ha−1 differed from a known glyphosate-susceptible biotype using Dunnett’s procedure (Table 2). When biotypes were treated with thifensulfuron at 70 g ha−1, 36% (mortality) and 30% (visible control) of biotypes differed from the thifensulfuron-susceptible biotype (Table 2). While this approach defines biotypes that most likely express homogeneity of the herbicide-resistance trait, it most likely underestimates resistance in populations in early stages of resistance expression or those that are segregating. Knowing the frequency of resistance at the initial stages of resistance is important in implementing practices quickly to minimize impact of herbicide resistance on the production system.
Percentage of biotypes expressing lower mortality and less visible control than a known susceptible biotype for each rate of glyphosate and thifensulfuron based on Dunnett’s Procedure (P≤0.05).
Herbicide
Rate (g ha−1)
Mortality
Visible control
Percentage of biotypes
F value
P>F
CV (%)
Percentage of biotypes
F value
P>F
CV (%)
Thifensulfuron
4.37
15
2.18
≤0.0001
95.2
25
7.73
≤0.0001
24.6
Thifensulfuron
17.5
30
3.00
≤0.0001
58.8
29
8.22
≤0.0001
19.8
Thifensulfuron
70
36
5.05
≤0.0001
52.5
30
12.54
≤0.0001
17.7
Glyphosate
280
78
6.54
≤0.0001
85.5
60
12.39
≤0.0001
57.8
Glyphosate
560
91
7.93
≤0.0001
92.3
76
6.74
≤0.0001
72.5
Glyphosate
840
95
11.49
≤0.0001
95.4
87
7.91
≤0.0001
77.3
To compare the change in frequency of resistance from 2005 to 2010, data from 2010 were assigned to categories similar to those defined by Whitaker [12]. The percentage of the populations resistant to glyphosate increased dramatically during this 5-yr period. Whitaker [12] observed that Palmer amaranth in 17% of 295 fields sampled in 2005 expressed resistance to glyphosate, and all of these fields were in the central and southern Coastal Plain (Figure 4). In 2010, Palmer amaranth in 128 of the 134 fields sampled, or greater than 98%, was resistant to glyphosate (Figure 3). All plants in the known susceptible biotype were killed completely by glyphosate at the lowest rate (data not shown). No control and no mortality were observed in the known resistant population with either of the lower two glyphosate rates. Only 14% control and 5% mortality were observed in the known resistant population with the highest rate of glyphosate (data not shown).
Distribution of glyphosate- and thifensulfuron-resistant Palmer amaranth in 2005, adapted from Whitaker [12].
Reported levels of Palmer amaranth resistance to glyphosate have varied among studies [10, 11, 17, 30]. Part of the discrepancy may be due to methodology and the level of susceptibility in the susceptible biotype to which resistant biotypes were compared. Some of the discrepancy is also likely due to varying degrees of homogeneity for resistance in the “resistant” populations. Similar to the survey in 2005 [12], populations in 2010 varied in response to glyphosate. Within some populations, all plants screened were resistant to the highest rate of glyphosate whereas in other populations some plants were killed by the lowest rate and some plants survived the highest rate, suggesting continued segregation of the populations (data not shown). The criterion for the “highly resistant” designation was based upon work by Whitaker [12]. One of the most resistant populations from the 2005 collection had a 20-fold level of resistance based upon I50 values for fresh weight reduction. Fresh weight of that population was reduced about 30% by glyphosate at 840 g ha−1 compared with 95% reduction by glyphosate at 240 g ha−1 of the same susceptible population as used in the current study. Sixty-seven percent of the nonglyphosate-susceptible populations in 2010 fit into the highly resistant category.
The procedure for collecting biotypes was biased toward finding glyphosate resistance. We did not attempt to determine the herbicide program used in the fields from which seeds were collected. However, with 90% or more of the cotton and soybean in North Carolina being planted to glyphosate-resistant cultivars [31], there was a high probability that any field from which seeds were collected had been treated with glyphosate, thus increasing the likelihood that Palmer amaranth present was resistant to glyphosate. Nevertheless, the results indicate that glyphosate-resistant biotypes of Palmer amaranth are now very common in the state and that glyphosate-only programs, once highly effective [5–8], will no longer be successful in most of the state’s agronomic crop production areas.
Levels of resistance to ALS-inhibiting herbicides vary greatly. Typically, resistant Amaranthus biotypes have very high levels of resistance [32–36]. We arbitrarily designated a population as highly resistant if mortality was 30% or less at 70 g ha−1, a rate which is 16 times greater than the manufacturer’s suggested use rate for non-STS soybean [26]. Ninety-seven percent of the populations (126 of 134) sampled in 2010 were found to be resistant to thifensulfuron (Figure 3). This is compared with only 18% of the populations exhibiting resistance in 2005 [12]. Among the 2010 populations exhibiting resistance, 17% were designated as highly resistant (data not shown). Designations of resistant or highly resistant were based upon the average response of the population. Lack of a greater percentage of the populations being designated as highly resistant was the result of continued segregation in the populations at time of collection. In every population, including those designated as susceptible, at least one plant in at least one run of the experiment was not completely killed by thifensulfuron at 70 g ha−1. Hence, some highly resistant individuals were present in every population. No attempt was made to determine if resistance to other ALS-inhibiting herbicides was present. However, resistance to chlorimuron has been previously confirmed in North Carolina Palmer amaranth [13]. Additionally, Whitaker [12] noted cross-resistance to thifensulfuron, pyrithiobac, and imazethapyr in selected Palmer amaranth populations. Resistance to ALS-inhibiting herbicides is predominately due to alterations of the target site enzyme, and multiple mutations have been identified [37, 38]. Cross-resistance among ALS-inhibiting herbicides is common in Palmer amaranth [37, 39, 40] and other Amaranthus species [32, 41, 42].
To further exasperate the problem with managing this weed, 124 (93%) of the Palmer amaranth populations exhibited multiple resistance to thifensulfuron and glyphosate (Figure 3). This is compared with less than 2% of the populations collected in 2005 exhibiting multiple resistance (Figure 4). No population was susceptible to both herbicides. Widespread resistance to glyphosate and thifensulfuron (and probably other ALS-inhibiting herbicides) will make controlling Palmer amaranth challenging and will force growers to diversify weed management strategies.
Glufosinate applied postemergence and fomesafen applied preemergence or postemergence control Palmer amaranth [8, 43–48]. Fomesafen can be applied preemergence or postemergence to soybean, and it is currently being widely used in North Carolina soybean. Fomesafen is also widely used in North Carolina cotton as a preemergence treatment. In recent years, glufosinate use in North Carolina cotton has increased rapidly. North Carolina cotton growers in 2013 planted 65% of their crop to cultivars that allow postemergence application of glufosinate [49], and this was primarily done to control glyphosate-resistant Palmer amaranth. Planting of glufosinate-resistant soybean is expected to increase as more locally adapted cultivars become available. No resistance to either fomesafen or glufosinate was observed among the 2010 populations. Glufosinate at all rates completely controlled all plants in all populations (data not shown). Fomesafen at 840 g ha−1 completely controlled all plants, and only a few plants were not controlled completely by 280 or 560 g ha−1 (data not shown). Plants not controlled completely by fomesafen exhibited typical injury symptoms. Although subjective, plant response to fomesafen at the lower rates appeared to be representative of a typical rate response to fomesafen for susceptible plants rather than a reflection of resistance.
Absence of evidence of resistance to fomesafen or glufosinate does not establish that resistant alleles are not present in these populations. Approximately 12,000 plants were screened for resistance to each herbicide when considering the number of populations, herbicide rates, number of plants per experimental unit, number of replications, and experiment repetition. Initial frequency of herbicide resistance would be expected to be very low [50], especially given Palmer amaranth control failures with fomesafen or glufosinate associated with possible resistance have not been reported. Initial frequency of resistance is postulated to be several orders of magnitude lower than the number of plants screened in this research [50]. Therefore, herbicide-resistant alleles may be present in these populations but at frequencies below those likely to be detected using this screening procedure.
Collectively, these results document very widespread resistance of Palmer amaranth to glyphosate and thifensulfuron (and most likely other ALS-inhibiting herbicides) in North Carolina. Fortunately, no resistance to fomesafen or glufosinate was detected, but these herbicides are being widely used. The extent of the problem that has developed with glyphosate and thifensulfuron resistance should be ample encouragement for growers to proactively manage to avoid resistance to other herbicide modes of action by using diverse strategies to manage weeds [51, 52].
Conflict of Interests
None of the authors has a conflict of interests in terms of the products mentioned in the paper.
Acknowledgments
This research was supported by the North Carolina Cotton Producers Association, the North Carolina Soybean Growers Association, and the North Carolina Peanut Growers Association. Rick Seagroves, Jamie Hinton, and Charles Cahoon assisted with sample collection.
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