Hostname: page-component-cd9895bd7-fscjk Total loading time: 0 Render date: 2024-12-23T01:28:39.324Z Has data issue: false hasContentIssue false

Baseline survey reveals glyphosate and dicamba resistance in broadleaf weeds before sugar beet trait introduction

Published online by Cambridge University Press:  30 October 2024

André Lucas Simões Araujo
Affiliation:
Graduate student, Colorado State University, Agricultural Biology Department, Fort Collins, CO, USA
Eric P. Westra
Affiliation:
Assistant Professor, Utah State University, Plants, Soils & Climate, Logan, UT, USA
Lovreet Shergill
Affiliation:
Assistant Professor, Montana State University, Southern Agricultural Research Center, Huntley, MT, USA Assistant Professor, Colorado State University, Agricultural Biology Department, Fort Collins, CO, USA
Todd A. Gaines*
Affiliation:
Professor, Colorado State University, Agricultural Biology Department, Fort Collins, CO, USA
*
Corresponding autho: Todd Gaines; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

A prelaunch survey of broadleaf weeds was conducted to predict the weed management efficacy of a novel genetically engineered sugar beet with resistance traits for glyphosate, dicamba, and glufosinate. We targeted problematic broadleaf weed species prevalent in sugar beet fields, including kochia, common lambsquarters, Palmer amaranth, and redroot pigweed in Colorado, Nebraska, and Wyoming. The results revealed that a significant percentage of kochia populations in Colorado, Nebraska, and Wyoming exhibited resistance to glyphosate (94%, 98%, and 75%, respectively) and dicamba (30%, 42%, and 17%, respectively). Palmer amaranth populations had resistance frequencies for glyphosate and dicamba of 80% and 20% in Colorado and 20% and 3% in Nebraska, respectively. No resistance to the tested herbicides was identified in common lambsquarters or redroot pigweed. Glufosinate resistance was not identified for any species. Kochia and Palmer amaranth populations from Colorado and Nebraska exhibited glyphosate resistance primarily through 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) gene amplification. However, one glyphosate-resistant kochia population from Wyoming lacked EPSPS gene amplification, indicating the presence of an alternative resistance mechanism. We identified the previously characterized IAA16 G73N substitution in a dicamba-resistant kochia population from Nebraska. However, dicamba-resistant kochia populations from Colorado did not possess this substitution, suggesting an alternative, yet-to-be-determined resistance mechanism. The widespread prevalence of glyphosate and dicamba resistance, coupled with the emergence of novel resistance mechanisms, poses a significant challenge to the long-term efficacy of this novel genetically engineered sugar beet technology. These findings underscore the urgent need for integrated weed management strategies that diversify effective herbicide sites-of-action and incorporate alternative weed management practices within cropping systems.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Weed Science Society of America

Introduction

The United States is a major global producer of Beta vulgaris (sugar beets), ranking fifth worldwide in 2022 with more than 29 billion kg having been produced (USDA 2023). Effective weed control strategies are crucial for the success of this crop, as slow-growing sugar beet seedlings are poor competitors against weeds (Gerhards et al. Reference Gerhards, Bezhin and Santel2017). Controlling weeds before and after sugar beet emergence is fundamental to maintaining yield and product quality (Bhadra et al. Reference Bhadra, Mahapatra and Paul2020). Before the introduction of genetically engineered traits in sugar beets, weed management in sugar beet production relied heavily on mechanical and cultural practices, and a limited number of herbicide options. This often led to challenges in weed management, potentially causing crop damage and yield loss (Lueck et al. Reference Lueck, Peters, Khan and Boetel2017).

Since the introduction of Roundup Ready sugar beet in 2008, glyphosate has substantially facilitated weed management and reduced the impact of weeds on sugar beet farms (Morishita Reference Morishita2018). Glyphosate is extensively used in current preemergence and postemergence weed management programs in sugar beet systems. Dicamba, while not used directly on sugar beets, is often applied with rotational crops such as wheat, barley, or corn and fallow (Bhadra et al. Reference Bhadra, Mahapatra and Paul2020; Cioni and Maines Reference Cioni and Maines2010). However, the efficacy of both glyphosate and dicamba has diminished in recent years, likely due to repeated application of glyphosate on sugar beet fields and both glyphosate and dicamba on rotational crops, which has accelerated the evolution of resistance in certain weed species (Jhala et al. Reference Jhala, Norsworthy, Ganie, Sosnoskie, Beckie, Mallory-Smith, Liu, Wei, Wang and Stoltenberg2020).

Kochia, Palmer amaranth, common lambsquarters, and redroot pigweed are among the most troublesome weeds in sugar beet systems, known for causing significant yield loss (Soltani et al. Reference Soltani, Dille, Robinson, Sprague, Morishita, Lawrence, Kniss, Jha, Felix and Nurse2018; Van Wychen Reference Van Wychen2016). Kochia, a C4 summer-annual broadleaf weed, is particularly notorious for its invasiveness, persistence, and prolific seed production (more than 100,000 seeds m−2) (Kumar and Jha Reference Kumar and Jha2015). Moreover, kochia exhibits remarkable tolerance to abiotic stressors such as low soil temperature, drought, soil salinity, and heat (Kumar et al. Reference Kumar, Jha, Jugulam, Yadav and Stahlman2019a). Its protogynous flowers promote outcrossing and gene flow, thereby increasing genetic diversity and potentially accelerating the spread of herbicide resistance (Martin et al. Reference Martin, Benedict, Wei, Sauder, Beckie and Hall2020). Kochia populations have been reported with resistance to several modes of action, including acetolactate synthase (ALS) inhibitors, synthetic auxins, and 5-enolpyruvylshikimate-3-phosphate synthase (EPSP) synthase inhibitors (Heap Reference Heap2024).

Common lambsquarters is an annual weed species that poses a significant challenge in sugar beet production (Bhadra et al. Reference Bhadra, Mahapatra and Paul2020). Capable of both self- and cross-pollination through wind and insect vectors, this weed exhibits a high reproductive capacity, with a single plant producing more than 70,000 seeds. This prolific seed production contributes to its rapid spread and persistence in sugar beet fields. Resistance has been documented in common lambsquarters for herbicides that inhibit photosystem II (PS II) and ALS (Heap Reference Heap2024). Reduced glyphosate translocation has been reported in common lambsquarters populations (Yerka et al. Reference Yerka, Wiersma, Lindenmayer, Westra, Johnson, de Leon and Stoltenberg2013). Glyphosate efficacy is affected by growth state in common lambsquarters, where plants taller than 7 cm exhibit greater tolerance than small plants (DeGreeff et al. Reference DeGreeff, Varanasi, Dille, Peterson and Jugulam2018; Sivesind et al. Reference Sivesind, Gaska, Jeschke, Boerboom and Stoltenberg2011).

Palmer amaranth and redroot pigweed are problematic weed species in sugar beet production, both sharing a prolonged emergence period that complicates management (Werle et al. Reference Werle, Sandell, Buhler, Hartzler and Lindquist2014). Palmer amaranth, an annual, dioecious plant species, is a prolific seed producer (Ward et al. Reference Ward, Webster and Steckel2013). As an obligate out-crosser with high genetic diversity and pollen-mediated gene flow, it readily develops herbicide resistance (Jhala et al. Reference Jhala, Norsworthy, Ganie, Sosnoskie, Beckie, Mallory-Smith, Liu, Wei, Wang and Stoltenberg2020; Sosnoskie et al. Reference Sosnoskie, Webster, Kichler, MacRae, Grey and Culpepper2012). Glyphosate-resistant and dicamba-resistant Palmer amaranth populations have been reported in several U.S. states (Foster and Steckel Reference Foster and Steckel2022; Kumar et al. Reference Kumar, Liu and Stahlman2020; Vieira et al. Reference Vieira, Samuelson, Alves, Gaines, Werle and Kruger2018). Redroot pigweed possesses similar morphological characteristics to Palmer amaranth but is monoecious and more prevalent in Colorado. Redroot pigweed can be challenging to manage in sugar beet production (Jursík et al. Reference Jursík, Holec, Soukup and Venclová2008; Soltani et al. Reference Soltani, Dille, Robinson, Sprague, Morishita, Lawrence, Kniss, Jha, Felix and Nurse2018).

Target-site resistance (TSR) to glyphosate, primarily through increased EPSPS gene copy number, has been reported in kochia and Palmer amaranth (Gaines et al. Reference Gaines, Patterson and Neve2019; Patterson et al. Reference Patterson, Saski, Sloan, Tranel, Westra and Gaines2019). This gene amplification can lead to high resistance levels, depending on the number of gene copies replicated (Gaines et al. Reference Gaines, Barker, Patterson, Westra, Westra, Wilson, Jha, Kumar and Kniss2016; Giacomini et al. Reference Giacomini, Westra and Ward2019; Godar et al. Reference Godar, Stahlman, Jugulam and Dille2015). TSR to dicamba, which involves mutations in the auxin receptor gene, has been reported in kochia populations, which drastically reduces dicamba efficacy (LeClere et al. Reference LeClere, Wu, Westra and Sammons2018; Wiersma et al. Reference Wiersma, Gaines, Preston, Hamilton, Giacomini, Robin Buell, Leach and Westra2015). A thorough understanding of these resistance mechanisms is crucial for developing effective and sustainable weed management strategies, including the implementation diversified herbicide programs, crop rotation, and the integration of alternative weed control tactics (Brunharo et al. Reference Brunharo, Gast, Kumar, Mallory-Smith, Tidemann and Beckie2022).

The ongoing development of a sugar beet variety with a triple stack trait conferring resistance to glyphosate, dicamba, and glufosinate is anticipated to improve postemergence weed management, particularly during the challenging early growth phase. While this stacked trait offers new possibilities for sugar beet weed management, the individual herbicides (glyphosate, dicamba, and glufosinate) are not new to agriculture. Glufosinate is not currently used in sugar beet systems, but TSR and non-TSR (NTSR) to this herbicide has been reported in multiple weed species in different cropping systems. Carvalho-Moore et al. (Reference Carvalho-Moore, Norsworthy, González-Torralva, Hwang, Patel, Barber, Butts and McElroy2022) identified TSR to glufosinate in Palmer amaranth accessions from Arkansas due to increased chloroplastic glutamine synthetase gene copy number and overexpression. A resistant Italian ryegrass population from Oregon was able to metabolite glufosinate faster than susceptible populations (Brunharo et al. Reference Brunharo, Takano, Mallory-Smith, Dayan and Hanson2019). A Palmer amaranth population from Anson County North Carolina was recently confirmed to be resistant to glufosinate when compared with susceptible lines of that weed from the same state (Jones et al. Reference Jones, Dunne, Cahoon, Jennings, Leon and Everman2024).

A previous survey (Westra et al. Reference Westra, Nissen, Getts, Westra and Gaines2019) conducted from 2011 to 2014 in Colorado reported resistance by kochia to glyphosate and dicamba. However, limited information is currently available regarding resistance to glyphosate, dicamba, and glufosinate among major weed species in sugar beet systems.

To address the concerns of growers and to predict the efficacy of upcoming herbicide-resistant sugar beet traits, we conducted a resistance survey in 2020 and 2021 across sugar beet–growing areas in Colorado, Nebraska, and Wyoming. The survey focused on four key weed species belonging to the Amaranthaceae family: kochia, Palmer amaranth, redroot pigweed, and common lambsquarters. Our objectives were 2-fold: 1) to determine the geographical distribution of glyphosate, dicamba, and glufosinate resistance across these regions; and 2) to investigate whether resistance observed in kochia, and Palmer amaranth populations was due to previously documented TSR mechanisms.

Materials and Methods

Sample Collection

Seeds were collected during autumn 2020 in Wyoming and Nebraska, and in 2021 in Colorado. The locations of sugar beet farms were obtained from the Western Sugar Cooperative, and all growers were contacted prior to the collection. A total of 37 sugar beet fields were visited in Colorado. Sample collection in Colorado included four species: kochia, Palmer amaranth, common lambsquarters, and redroot pigweed. In Nebraska, seeds of kochia, Palmer amaranth, and common lambsquarters were collected, while only kochia samples were collected in Wyoming. The collection was conducted by driving transects, ensuring a minimum distance of 8 km between each cropping area. To minimize sampling bias, sugar beet fields along the border and on side roads were specifically targeted, regardless of reported herbicide efficacy. At each collection site, 10 to 15 plants of each target weed species were threshed, and the seeds were combined to form a population sample. The latitude and longitude coordinates of each area were recorded and georeferenced using a portable GPS device (Geo XH 2005 series; Trimble Boulder, Boulder, CO). Samples from Nebraska and Wyoming along with location data were sent to Colorado State University by mail from the Western Sugar Cooperative.

Greenhouse Planting Procedures

To obtain a representative sample from each collection site, seeds of kochia, common lambsquarters, redroot pigweed, and Palmer amaranth were threshed from 10 to 15 dried mature plants in the field, and seeds where combined for each sampling location. Individual seeds from each population were then planted using pot soil LM-GPS germination, plugs, and seedling (Lambert Peat Moss Inc., Riviere-Ouelle, QC, Canada) in a plug tray (1.3 cm × 1.3 cm × 2.5 cm, TOP 200 Plug Tray 2.125 Deep Black; Griffin, Tewksbury, MA). Seedlings were grown to a height of 3 cm before being transplanted into larger pots (3.8 cm × 3.8 cm × 5.8 cm, Dillen CTS332PF Tray Black and 32 Pocket Square Carry Tray 03.00 Pot; Griffin). When plants were at the 5- to 7-cm height, a total of 96 plants per population (32 individuals per herbicide) were screened for resistance to glyphosate, dicamba, and glufosinate alongside a known susceptible line, originally from western Nebraska (Preston et al. Reference Preston, Belles, Westra, Nissen and Ward2009). Plants were maintained in a greenhouse at 26/22 ± 2 C day/night, and a 14/10 h light/dark photoperiod. Additionally, they were irrigated daily to ensure they remained at field capacity of soil-less media.

Herbicide Applications

Each collected population was individually screened for resistance to glyphosate, dicamba, and glufosinate. Plants were treated with glyphosate (RoundUp Weathermax®, 840 g ae ha−1; Bayer CropScience, St. Louis, MO) with ammonium sulfate at a concentration of 20 g L−1; dicamba (Engenia®, 280 g ae ha−1; BASF, Research Triangle Park, NC) with a nonionic surfactant (Induce®; BASF) at a concentration of 0.25% v/v, and glufosinate (Liberty®, 590 g ai ha−1; BASF) also with a nonionic surfactant at a concentration of 0.25% v/v. Adjuvants were included based on herbicide-label recommendations for each herbicide. Herbicide applications were carried out using a single-nozzle spray chamber (DeVries Generation III Research Sprayer; Hollandale, MN), calibrated to deliver 187 L ha–1. Phenotype was characterized by comparing each treated population to a known susceptible reference and an untreated control for each species. Individual plants that survived were visually assessed and categorized as resistant if they remained alive after a 4-wk period, regardless of herbicide injury. Survival frequency (%) was calculated by dividing the number of survivors at each herbicide rate by the total number of screened plants. Phenotype classification followed a previously established percentage scale (Owen et al. Reference Owen, Walsh, Llewellyn and Powles2007) in which populations with <1% survivors were categorized as susceptible, those with 1% to 19% survivors were classified as low resistance, and populations with >20% survivors were classified as resistant. Collection sites were georeferenced, and maps were created using QGIS software (version 3.28.3) from the QGIS Geographic Information System, Open-Source Geospatial Foundation Project (http://qgis.org). The WGS84 coordinate system (EPSG:4326) was used. The relationship between kochia glyphosate and dicamba resistance was examined via Fisher’s exact test to investigate whether resistance to one herbicide was associated (P < 0.05) with resistance to the other. The general null hypothesis for this test is that categorical variables (phenotype classification) are independent (Nowacki Reference Nowacki2017); in other words, glyphosate resistance has no influence on dicamba resistance and vice versa. Heatmaps were generated with R statistical software (v. 4.1.2; R Core Team 2021) using the ggplot2 package (Wickham Reference Wickham2016). The matrix heatmaps were based on contingency tables displaying the proportions of populations classified as susceptible, low resistant, or resistant to both glyphosate and dicamba. Palmer amaranth associations were not analyzed due to the low sample size in this study.

Laboratory Assays

Known TSR mechanisms were investigated for weed populations categorized as resistant (>20% survival). Glyphosate and dicamba TSR mechanisms were investigated for kochia, while only the glyphosate TSR mechanism was investigated for Palmer amaranth, because there are no reports of dicamba TSR mechanisms for this species in the literature. Increased EPSPS copy number was assessed for all collection sites where populations were categorized as resistant. Young tissue material (100 mg) was collected 28 d after glyphosate treatment from three randomly selected survivors and placed into a separated 2-mL Eppendorf tubes in liquid nitrogen and stored at −20 C when not in use. Samples were homogenized using a TissueLyser II (QIAGEN Sciences, Germantown MD). Genomic DNA extraction from each sample was conducted using a Zymo Quick DNA extraction kit (Zymo Research, Irvine, CA). Genomic DNA was eluted in 50 μL of nuclease-free water, and concentration and quality were verified using a NanoDROP 1000 UV-Vis Spectrophotometer (Thermo Fisher Scientific, Waltham, MA). Relative EPSPS copy number was determined using quantitative polymerase chain reaction (qPCR) on the genomic DNA. The primers have been previously described (Gaines et al. Reference Gaines, Slavov, Hughes, Küpper, Sparks, Oliva, Vila-Aiub, Garcia, Merotto and Neve2021). The ALS gene was used as a single copy reference gene. Each qPCR reaction was 20 μL, including 10 μL of PerfeCTa SYBR® green Supermix (Quanta Biosciences, Beverly, MA), 1.2 μL of the forward and reverse primers (5 μM final concentration), 5 μL of gDNA (10 ng), and 2.6 μL of nuclease-free water. Reactions were performed in a CFX Connect Real-Time PCR machine (Bio-Rad Laboratories, Hercules, CA). The temperature for each of the reactions was used as follows: the denaturation step was held at 95 C for 3 min, followed by 30 cycles of denaturation at 95 C for 30 s, and an annealing/extension step at 72 C for 30 s. Fluorescence measurements were taken after each cycle. Melt curve analysis was conducted to determine the number of PCR products formed in each reaction where temperature was increased from 65 C to 95 C in 0.5 C increments. Melt-curve analysis using both EPSPS and ALS primers revealed only a single PCR product, confirming that the PCR amplifications were specific to the intended genes, thereby ensuring the reliability and accuracy of the PCR reaction. Relative EPSPS gene copy number was determined using the 2ΔCt(ΔCt = CtALS − CtEPSPS) method (Schmittgen and Livak Reference Schmittgen and Livak2008). This method was applied to kochia and Palmer amaranth using three biological replicates, each from a different surviving plant, and two technical replicates per biological replicate. Mean and standard deviation of the mean of the relative EPSPS copy number was calculated for each population. To establish a reference for comparison and verify assay accuracy, a resistant kochia population from Akron, CO, with elevated EPSPS copy number (Gaines et al. Reference Gaines, Barker, Patterson, Westra, Westra, Wilson, Jha, Kumar and Kniss2016) and a known susceptible population were included as positive and negative controls, respectively. A non-template control with nuclease-free water was included in each qPCR reaction to ensure accuracy and reliability of the method.

The dicamba TSR mechanism was investigated in populations of kochia classified as resistant in the previous greenhouse screening. The AUX/IAA16 (GenBank accession number MF376149.1) gene was Sanger-sequenced to verify the presence of the previously reported G73N substitution in the degron region (LeClere et al. Reference LeClere, Wu, Westra and Sammons2018). Young tissue material (100 mg) was collected 28 d after dicamba treatment from three randomly selected survivors and placed into separate 2-mL Eppendorf tubes in liquid nitrogen and stored at −80 C when not in use. RNA extraction was conducted using a Quick RNA extraction kit following the manufacturer’s recommendations (Zymo Research). Extracted RNA was checked for quality and quantity using a NanoDROP 1000 UV-Vis Spectrophotometer (Thermo Fisher), employing the same methodology used for glyphosate previously described. Subsequently, complementary DNA (cDNA) was synthesized from the RNA product using a ProtoScript® II kit (Fisher Scientific) with random primers. PCR detection was performed using 1 μL of cDNA, 12.5 μL of EconoTaq® PLUS 2× Master Mix (Lucigen, Middleton, WI), 2 μL of the forward primer, 2 μL of the reverse primer, and 7.5 μL of water, resulting in a total volume of 25 μL for each sample. PCR primers were described previously (Montgomery et al. Reference Montgomery, Soni, Marques Hill, Morran, Patterson, Edwards, Ratnayake, Hung, Pandesha and Slotkin2024). PCR products were visualized on a 1.0% agarose gel stained with Biotium GelRed® Nucleic Acid Gel Stain, 10,000X, 0.5 mL in dimethyl sulfoxide following the manufacturer’s recommendations (Biotium Inc., Fremont, CA). The PCR products were then processed for Sanger sequencing by GENEWIZ (South Plainfield, NJ).

Results and Discussion

Glyphosate Resistance Status

A total of 37 sugar beet fields were surveyed across eastern Colorado to assess the presence of weeds at sugar beet harvest. In total, 97.30% of the surveyed fields were infested with kochia (Figure 1), 13.51% had Palmer amaranth (Supplementary Figure S1), 62.16% had common lambsquarters (Supplementary Figure S2), and 48.65% had redroot pigweed (Supplementary Figure S3). In Nebraska, 100% of the surveyed fields had kochia (Figure 2), 12% had Palmer amaranth (Supplementary Figure S4), and 22% had common lambsquarters (Supplementary Figure S5). In Wyoming, only kochia was targeted and was present in 100% of the surveyed fields (Figure 3). Among these weed species, kochia was likely the most problematic in Colorado, Nebraska, and Wyoming sugar beet farms, because this weed species was present and widespread in most of the survey collection areas.

Figure 1. Geo-referenced map illustrating the Bassia scoparia (kochia) populations collected in Colorado during fall 2021. The dots on the map represent the locations of kochia populations, and their color signifies their response to glyphosate treatment (A), dicamba (B), and glufosinate (C). On the left a map illustrates the distribution of the populations in a state overview. On the right, a close-up map focuses on the main counties where the samples were collected. Populations classified as resistant (>20% survival) are represented by red dots, yellow dots indicate low frequency (1% to 19% survival), and green dots represent susceptible populations (0% survival).

Figure 2. Geo-referenced map illustrating the Bassia scoparia (kochia) populations collected in Nebraska during fall 2020. The dots on the map represent the locations of kochia populations, and their color signifies their response to glyphosate treatment (A), dicamba (B), and glufosinate (C). On the left, a map illustrates the distribution of the populations in a state overview. On the right, a close-up map focuses on the main counties where the samples were collected. Populations classified as resistant (>20% survival) are represented by red dots, yellow dots indicate low frequency (1% to 19% survival), and green dots represent susceptible populations (0% survival).

Figure 3. Geo-referenced map illustrating the Bassia scoparia (kochia) populations collected in Wyoming during fall 2020. The dots on the map represent the locations of kochia populations, and their color signifies their response to glyphosate treatment (A), dicamba (B), and glufosinate (C). On the left, a map illustrates the distribution of the populations in a state overview. On the right, a close-up map focuses on the main counties where the samples were collected, including the highlighted blue squares where a few samples were collected in southeastern Wyoming. Populations classified as resistant (>20% survival) are represented by red dots, yellow dots indicate low frequency (1% to 19% survival), and green dots represent susceptible populations (0% survival).

Screening of kochia accessions from Colorado revealed that around 75% of the collected samples were classified as resistant, 19% exhibited low resistance, and 6% were susceptible. In Nebraska (Figure 2A), 86% of populations were classified as resistant, 12% as low resistance, and only 2% as susceptible. In Wyoming (Figure 3A), 33% of kochia accessions were categorized as resistant, 42% as low resistance, and 25% as susceptible.

The glyphosate-resistance trait was adopted by 85% to 90% of sugar beet producers in the first year of commercialization in Colorado, Wyoming, and Nebraska (Khan Reference Khan2010). After 15 yr of using this technology, weed management strategies continue to heavily rely on glyphosate for in-crop and fallow applications, making it the primary method for controlling weeds in sugar beet systems (Kniss Reference Kniss2018; Morishita Reference Morishita2018). This reliance on glyphosate likely contributes to the evolution of resistance over time by selecting resistant populations. The evolution of glyphosate resistance in kochia populations is a significant issue in North America, recorded in multiple states and provinces throughout the United States and Canada (Heap Reference Heap2024). For instance, a 2014 survey of kochia in 96 populations primarily from wheat-fallow systems in eastern Colorado showed that 23% of accessions were resistant to glyphosate (Westra et al. Reference Westra, Nissen, Getts, Westra and Gaines2019). In Canada, a 2018 survey in Manitoba identified a resistance rate of 59% at 315 sites, with the highest frequency of glyphosate-resistant kochia in glyphosate-resistant crops such as soybean and corn (Geddes et al. Reference Geddes, Pittman, Gulden, Jones, Leeson, Sharpe, Shirriff and Beckie2021). In southern Saskatchewan, researchers identified a high occurrence of glyphosate- and dicamba-resistant kochia populations, with 87% found to be resistant to glyphosate and 45% to dicamba (Sharpe et al. Reference Sharpe, Leeson, Geddes, Willenborg and Beckie2023). Likewise, our study uncovered a significant proportion of glyphosate-resistant populations (Figure 4), with frequencies of 94%, 98%, and 75% in Colorado, Nebraska, and Wyoming, respectively, considering both low-resistant and resistant populations.

Figure 4. Frequency of observed phenotypes of kochia (left) and Palmer amaranth (right) populations collected from Colorado, Nebraska and Wyoming during fall 2020 and 2021, following treatment in a greenhouse setting with glyphosate, dicamba, and glufosinate. Bar colors represent the phenotype characterization: green (dashed to the right) represent susceptible populations (0% survival), yellow represents low resistance (1% to 19% survival), and red (dashed to the left) represent populations classified as resistant (>20% survival).

In general, kochia exhibited minimal to no damage following glyphosate treatment at the field-use rate. A copy number variation assay targeting EPSPS genes revealed that all surviving individuals from Colorado and Nebraska exhibited a higher number of EPSPS gene copies (more than three) compared with a known susceptible single EPSPS gene copy reference (Figure 5). This explains the observed resistance phenotype, although additional underlying mechanisms could exist. For instance, one kochia population from Wyoming was classified as resistant, but individual survivors did not show an increased copy number (Figure 6). The resistance mechanism in this population remains unknown, and there are no reports of other resistance mechanisms in kochia apart from EPSPS gene amplification. Previous studies have shown a correlation between increased EPSPS copies and reduced glyphosate efficacy, corresponding to increased resistance levels (Gaines et al. Reference Gaines, Barker, Patterson, Westra, Westra, Wilson, Jha, Kumar and Kniss2016; Godar et al. Reference Godar, Stahlman, Jugulam and Dille2015). This resistance mechanism has been observed in various weed species, such as Palmer amaranth, weedy sunflower, and Russian thistle, none of which were controlled by glyphosate (Gaines et al. Reference Gaines, Shaner, Ward, Leach, Preston and Westra2011; Singh et al. Reference Singh, Etheredge, McGinty, Morgan and Bagavathiannan2020; Yanniccari et al. Reference Yanniccari, Palma-Bautista, Vázquez-García, Gigon, Mallory-Smith and De Prado2023). The presence of multiple copies of this gene results in more target enzymes, reducing glyphosate effectiveness at field-use rates (Wiersma et al. Reference Wiersma, Gaines, Preston, Hamilton, Giacomini, Robin Buell, Leach and Westra2015). Nuclear inheritance of resistance plays a role in the dissipation of increased gene copy number across generations, which may be an important factor contributing to the evolution of glyphosate resistance in kochia (Jugulam et al. Reference Jugulam, Niehues, Godar, Koo, Danilova, Friebe, Sehgal, Varanasi, Wiersma and Westra2014). This implies that a susceptible plant can produce resistant offspring if it gets pollinated by a resistant plant. In addition, the evolution of resistance may be facilitated by seed and pollen gene flow, along with the natural protogynous characteristics of kochia that enable cross-pollination. Additionally, kochia’s ability to function as a tumbleweed and disperse seeds over long distances facilitates the spread of herbicide resistance in this species (Beckie et al. Reference Beckie, Blackshaw, Hall and Johnson2016). Geddes et al. (Reference Geddes, Pittman, Gulden, Jones, Leeson, Sharpe, Shirriff and Beckie2021) observed a drastic reduction in glyphosate efficacy in controlling kochia over the years, mainly in areas with glyphosate-resistant crops, where they identified 78% and 70% of glyphosate-resistant kochia populations in soybean and corn areas, respectively. The same authors observed an increase in glyphosate resistance ranging from 1% to 59% in just 5 yr. A survey conducted among stakeholders in Nebraska revealed that glyphosate was the primary postemergence herbicide used in glyphosate-resistant corn and soybean crops, and kochia was one of the top five weeds considered most challenging to manage statewide (Sarangi and Jhala Reference Sarangi and Jhala2018). The nearly exclusive reliance on glyphosate for in-crop postemergence weed control in glyphosate-resistant soybean fields in Brazil has led to the emergence of resistant weed species such as horseweed [Conyza sumatrensis (Retz.) E.H. Walker], Italian ryegrass (Lolium multiflorum Lam.), and sourgrass [Digitaria insularis (L.) Mez ex Ekman] (Adegas et al. Reference Adegas, Correia, da Silva, Concenço, Gazziero and Dalazen2022; Correia and Durigan Reference Correia and Durigan2010). Given the high prevalence of glyphosate resistance in kochia, especially in Nebraska, the glyphosate resistance trait in the new triple-stack sugar beet may offer limited benefits for kochia management when used alone. Nonetheless, glyphosate remains an effective tool for managing other susceptible weed species and can be integrated into a broader integrated weed management (IWM) approach to prevent the evolution of herbicide resistance.

Figure 5. Relative EPSPS gene copy number in kochia populations collected from Colorado. The green and red bars represent the sensitive and resistant references (Sen and Res), respectively. The blue bars labeled as A represent resistant populations (>20% survival) surveyed from Colorado. Each bar represents the mean of the relative EPSPS copy number from three biological replicates (shown as grey circles) within each population, with error bars indicating the standard deviation.

Figure 6. Relative EPSPS gene copy number in kochia populations collected from Nebraska and Wyoming. The green and red bars represent the sensitive and resistant references (Sen and Res), respectively. The blue bars labeled as NEK represent Nebraska kochia populations, and WYK represents Wyoming kochia populations. Each bar represents the mean of the relative EPSPS copy number from three biological replicates (shown as grey circles) within each population, with error bars indicating the standard deviation.

Only a few accessions of Palmer amaranth were identified and collected in Colorado (Supplementary Figure S1) and Nebraska (Supplementary Figure S4), and none were collected in Wyoming. Based on our survey, four out of the five Palmer amaranth populations collected in Colorado were resistant to glyphosate, representing 80% of the total population. For Nebraska, of the eight populations collected, one was classified as resistant (13%), three as low resistant (38%) and four as susceptible (48%) (Supplementary Figure S4). The relatively low number of Palmer amaranth populations in these areas could be attributed to dry and cold weather, which is distinct from the southwestern United States and northwestern Mexico, where this species is indigenous (Ward et al. Reference Ward, Webster and Steckel2013). Despite the relatively low number of Palmer amaranth populations that were identified, it is alarming that the majority of these populations in Colorado have been classified as being resistant to glyphosate. Due to its dioecious nature, this species has a high potential for evolving and spreading resistance through gene flow via pollen, similarly as kochia. Most of the identified resistance mechanisms so far have been nuclear inherited, including gene amplification, which contributes to rapid herbicide resistance evolution (Murphy and Tranel Reference Murphy and Tranel2019). In all surveyed populations classified as resistant, an increase in relative EPSPS gene copy number was observed compared with the negative control (Figure 7), which possessed one copy of EPSPS. Resistance to glyphosate in Palmer amaranth accessions has been well-documented in various studies from different parts of the United States. Gaines et al. (Reference Gaines, Zhang, Wang, Bukun, Chisholm, Shaner, Nissen, Patzoldt, Tranel and Culpepper2010) reported that some populations of Palmer amaranth had 160-fold more copies of the EPSPS gene than a known susceptible population from Georgia. While glyphosate-resistant Palmer amaranth populations have been reported in 26 states (Heap Reference Heap2024) including recent confirmation of high EPSPS gene copy number in glyphosate-resistant Palmer amaranth in New York (Butler-Jones et al. Reference Butler-Jones, Maloney, McClements, Kramer, Morran, Gaines, Besançon and Sosnoskie2024), there have been no previous reports of glyphosate-resistant Palmer amaranth in Colorado until now.

Figure 7. Relative EPSPS gene copy number in Palmer amaranth populations collected from Colorado and Nebraska. Known sensitive (Sen) and resistant (Res) Palmer amaranth populations were used as positive and negative controls. The blue bars labeled as COP represent Colorado Palmer amaranth populations classified as resistant (>20% survival), while the blue bar labeled as NEP represents a Nebraska Palmer amaranth population. Each bar represents the mean and standard deviation of the Relative EPSPS copy number from three biological replicates (shown as grey circles) within each population.

Common lambsquarters was surveyed in Colorado and Nebraska, whereas redroot pigweed was identified in Colorado only. All the herbicides tested provided 100% control of common lambsquarters and redroot pigweed populations surveyed, and populations were classified as susceptible (Supplementary Figures 2, 3, and 5). Populations of common lambsquarters have been identified as resistant to ALS- and PS II-inhibiting herbicides, and very recently, to auxin herbicides (Ghanizadeh et al. Reference Ghanizadeh, He, Griffiths, Harrington, Carbone, Wu, Tian, Bo and Xinhui2024; Huang et al. Reference Huang, Zhou, Zhang, Jiang, Huang and Wei2020; McKenzie-Gopsill et al. Reference McKenzie-Gopsill, Graham, Laforest, Ibarra, Hann and Wagg2020). Several studies have highlighted inconsistencies in glyphosate efficacy for controlling common lambsquarters, likely due to the species’ varying tolerance to the herbicide at different growth stages. Additionally, reduced efficacy of glyphosate could be influenced by environmental conditions such as rainfall occurring after herbicide applications. Schuster et al. (Reference Schuster, Shoup and Al-Khatib2007) observed a decrease in glyphosate efficacy from 80% injury in 2.5-cm plants to 55% in 7.5- to 15-cm plants at 21 d after application. Sivesind et al. (Reference Sivesind, Gaska, Jeschke, Boerboom and Stoltenberg2011) noticed a reduction in glyphosate efficacy associated with growth stage, where the ED50 (the effective dose for 50% control) was three times higher in 20-cm plants compared with 10-cm plants. Enhanced glyphosate response in plants at the 5- to 7-cm growth stage was reported compared with plants that varied from 10 to 21 cm in height, particularly in cooler temperatures, when treated with glyphosate at a rate of 840 g ae ha−1 (DeGreeff et al. Reference DeGreeff, Varanasi, Dille, Peterson and Jugulam2018). In our survey, common lambsquarters accessions were effectively controlled when treated at a height of 5 to 7 cm under controlled conditions in a greenhouse setting. These findings underscore the importance of timing and appropriate management strategies for this weed species.

There have been few reported cases of herbicide resistance in both common lambsquarters and redroot pigweed across different modes of action when compared to kochia and Palmer amaranth, with most cases being related to TSR mechanisms to PS II inhibitors. It has been well documented that resistance to PS II inhibitors is primarily maternally inherited (Ghanizadeh et al. Reference Ghanizadeh, Buddenhagen, Harrington and James2019). Unlike kochia and Palmer amaranth, these weed species have limited mechanisms for spreading resistance. Common lambsquarters and redroot pigweed are predominantly autogamous, meaning that gene flow occurs predominantly by individual plants. A recent study by Moghadam et al. (Reference Moghadam, Alebrahim, Mohebodini and Macgregor2023) demonstrated that common lambsquarters and redroot pigweed exhibit low genetic diversity within populations but high diversity compared to other populations. This suggests that each population is distinct and requires an independent approach to weed management, with particular focus on controlling seed production and preventing seedbank replenishment. Here we highlight that the new sugar beet trait may contribute to the management of these two species by providing additional postemergence herbicide options. However, it is important to consider that resistance to glyphosate and dicamba has been reported in redroot pigweed and common lambsquarters in other regions of the United States (Heap Reference Heap2024; Rahman et al. Reference Rahman, James and Trolove2014), highlighting the importance of integrating this technology into a diversified weed management programs to mitigate future resistance risks. Additionally, it is crucial to implement practices that prevent the spread of resistant seeds, such as thoroughly cleaning equipment between fields and using certified weed-free seed. Mitigating the evolution of herbicide resistance in these species requires careful attention to seed dispersal and the implementation of effective management strategies.

Dicamba Resistance Status

Kochia populations classified as resistant were identified in Colorado (Figure 1B) and Nebraska (Figure 2B) and at low frequencies in Wyoming (Figure 3B). In Colorado, 8% of the populations were categorized as resistant, 22% as low resistant, and 70% as susceptible. The survival frequency within the resistant populations in Colorado ranged from 56% to 88%. In Nebraska, 50 populations were surveyed, and one was classified as dicamba resistant, representing 2% of the total collection sites surveyed. Meanwhile, 40% of the populations showed low resistance, and 58% were susceptible. In Wyoming, 83% of the kochia populations surveyed were susceptible, 17% showed low resistance, and none were categorized as resistant. One Palmer amaranth population out of five collected in Colorado was classified as dicamba resistant (Supplementary Figure S6), corresponding to 20% of survival frequency, and 80% were classified susceptible. For Nebraska out of eight populations (Supplementary Figure S7), 0% were resistant, 38% demonstrated low resistance and 49% were susceptible. Our data indicate a limited number of dicamba-resistant populations exist in these states compared to glyphosate resistance; however, a notable proportion of populations categorized as low resistant (with survival rates ranging from 1% to 20%) were identified. It is essential to reemphasize that this classification does not inherently imply that these populations are more sensitive to the herbicide compared with individual survivors within a resistant population. Rather, these populations may exhibit heterogeneity, and justifying the heterogeneity and the resistant trait is likely segregating within each population. The frequency and uniformity of a resistant phenotype within a population will depend on the species’ capacity to evolve and spread resistance, which is also strongly influenced by management practices over the years (in-crop versus fallow applications) implemented on sugar beet farms. In other words, a collection site that currently possess a low resistant frequency could potentially evolve to a population categorized as resistant in subsequent years if the selection pression for dicamba is intensive. It is worth noting that this topic remains controversial, and some authors may consider the resistance in development as a classification for population with low resistance frequency.

There was no significant association between glyphosate and dicamba among resistant kochia populations from Colorado and Wyoming; however, in Nebraska, a relationship between the phenological classification was observed (P < 0.05) (Figure 8). In all three states, dicamba-resistant kochia populations were always either resistant or demonstrated low resistance to glyphosate. In contrast, there were glyphosate-resistant populations that were not resistant to dicamba. This suggests that dicamba-resistant populations are more likely to have glyphosate resistance, and fields with glyphosate-resistant kochia may or may not contain dicamba resistance.

Figure 8. Matrix heatmaps of glyphosate and dicamba resistance in kochia populations across Colorado (A), Nebraska (B), and Wyoming (C). Heatmaps show the frequency of kochia populations categorized by phenotypic classifications (susceptible, low resistant, and resistant) to glyphosate and dicamba in Colorado, Nebraska, and Wyoming. The colors represent the number of observations in each category, with darker shades indicating higher frequencies. A Fisher’s exact test was performed to assess the statistical significance of associations between glyphosate and dicamba resistance. The test statistics and P-values are displayed within each heatmap. Associations are considered significant if the P-value is < 0.05.

The lack of significance (P > 0.05) in Colorado and Wyoming does not necessarily indicate an absence of association between the two-way resistance. The contingency tables in this study (Figure 8) contained expected values lower than five, which may compromise the statistical test. Low expected values and small sample sizes may result in reduced statistical power, thus increasing the likelihood of a Type II error, in which a true effect is not detected (Freiman et al. Reference Freiman, Chalmers, Smith, Kuebler, Bailar and Mostelle2019). The observed lack of association (P > 0.05) could also mean that the categorical variables are not linked, or in other words, resistance to both herbicides is independent, but this is unlikely the case, as was previously discussed.

Although there are no reports of dicamba-resistant kochia in sugar beet systems, the issue of resistance to auxin-mimic herbicides is a growing problem in the United States, with reports of dicamba resistance emerging as early as the 1990s (Keith et al. Reference Keith, Kalinina and Dyer2011; Preston et al. Reference Preston, Belles, Westra, Nissen and Ward2009). Since then, several other cases have been reported in six states and provinces in the United States and in Canada (Beckie et al. Reference Beckie, Hall, Shirriff, Martin and Leeson2019; Geddes et al. Reference Geddes, Owen, Ostendorf, Leeson, Sharpe, Shirriff and Beckie2022; Heap Reference Heap2024; Kumar et al. Reference Kumar, Engel, Currie, Jha, Stahlman and Thompson2019b; Westra et al. Reference Westra, Nissen, Getts, Westra and Gaines2019). The rapid spread of glyphosate-resistant kochia populations has led to an increased use of dicamba as an alternative in several crop systems, as well as raising the number of resistance cases (Ou et al. Reference Ou, Thompson, Stahlman and Jugulam2018a). Most dicamba-resistant cases reported thus far have been identified in cereal crop systems such as corn, sorghum, and wheat, where dicamba is extensively employed in crop management (Heap Reference Heap2024). A 2021 survey revealed a dicamba-resistant Palmer amaranth from Tennessee in dicamba-resistant soybean and cotton crop systems, but the resistance mechanism remains unknown (Foster and Steckel Reference Foster and Steckel2022). Dicamba-resistant Palmer amaranth has not been reported in Colorado until now (Supplementary Figure S6), and further analyses are underway to validate this phenotype.

All kochia and Palmer amaranth populations from Colorado categorized as dicamba-resistant were also categorized as glyphosate-resistant, whereas the population from Nebraska that was classified as dicamba-resistant was classified as having low resistance to glyphosate. In this survey, we observed that glyphosate-resistant and dicamba-resistant kochia and Palmer amaranth are emerging issues within the sugar beet–growing areas in the Central Great Plains even before the trait is released. The use of a combination of glyphosate and dicamba is a very common practice in the fallow season; however, studies have shown that this practice might not be the most optimal for managing weed resistance in some cases. Ou et al. (Reference Ou, Thompson, Stahlman, Bloedow and Jugulam2018b) demonstrated that applying glyphosate and dicamba in combination led to reduced translocation of both herbicides, significantly compromising their performance and leading to a poor control of kochia populations. Pesticide mixtures can have a dual evolutionary effect due to continuous selection. They may reduce TSR by combining herbicides from different chemical groups, but they can also increase the risk of NTSR developing through generalist mechanisms such as enhanced metabolism (Comont et al. Reference Comont, Lowe, Hull, Crook, Hicks, Onkokesung, Beffa, Childs, Edwards, Freckleton and Neve2020). Rigon et al. (Reference Rigon, Cutti, Turra, Ferreira, Menegaz, Schaidhauer, Dayan and Gaines2023) demonstrated that herbicide mixtures at sublethal doses may have led to a recurrent selection of barnyardgrass [Echinochloa crus-galli (L.) P.Beauv.] populations and decreased herbicide sensitivity during the years that may potentially be associated with selection of detoxifying genes and NTSR mechanisms. Currently, four known auxin TSR mechanisms have been identified in weeds, occurring in the degron region of Aux/IAA proteins. In the presence of auxin, the degron region of Aux/IAA interacts with the SCFTIR/AFB complex, promoting the polyubiquitylation of the Aux/IAA repressor. This process leads to the transcription of genes that generate auxin responses through auxin-responsive factors (de Figueiredo and Strader Reference de Figueiredo and Strader2022). Mutations in the degron region can disrupt the interaction between auxin herbicides and the Aux/IAA-SCFTIR/AFB complex, hindering polyubiquitylation of the repressor and thereby preventing auxin responses, which results in reduced herbicide efficacy. In kochia populations, an amino acid substitution in the degron region of the Aux/IAA co-receptor gene IAA16 has been reported as the causative factor for the observed resistance phenotype (LeClere et al. Reference LeClere, Wu, Westra and Sammons2018). A transposable element insertion in IAA16 led to a disruption of a normal gene splicing, causing a substitution of a specific glycine in the degron region of Aux/IAA, which is associated with dicamba resistance in kochia (Montgomery et al. Reference Montgomery, Soni, Marques Hill, Morran, Patterson, Edwards, Ratnayake, Hung, Pandesha and Slotkin2024). Very recently, a new amino acid substitution was reported in the degron region of the IAA16 gene in common lambsquarters that is associated with dicamba resistance (Ghanizadeh et al. Reference Ghanizadeh, He, Griffiths, Harrington, Carbone, Wu, Tian, Bo and Xinhui2024). In Indian hedge mustard a deletion has been identified in the degron tail region of the Aux/IAA co-receptor gene IAA2, resulting in 2,4-D resistance (de Figueiredo et al. Reference de Figueiredo, Küpper, Malone, Petrovic, de Figueiredo, Campagnola, Peersen, Prasad, Patterson, Reddy, Kubeš, Napier, Dayan, Preston and Gaines2022b). Enhanced metabolic detoxification of fluroxypyr and reduced translocation of 2,4-D have been reported in kochia and Sumatran fleabane, respectively (Leal et al. Reference Leal, Souza, Borella, Araujo, Langaro, Chapeta, Amorim, Silva, Morran, Zobiole, Gaines and Pinho2022; Todd et al. Reference Todd, Patterson, Westra, Nissen, Araujo, Kramer, Dayan and Gaines2024).

The presence of the G73N amino acid substitution in the degron region of the AUX/IAA16 gene complex was investigated as the TSR mechanism in three kochia populations from Colorado (A5, A22, and A32) and one from Nebraska (NEK 30) that were categorized as resistant in our survey screening. Upon sequencing the AUX/IAA16 gene in dicamba-surviving individuals, populations from Colorado did not exhibit any amino acid substitution in this region. However, all surviving individuals from the Nebraska population NEK30 had the G73N substitution (Figure 9). The G73N hinders the degradation of the AUX/IAA protein signaled through dicamba binding and TIR/AFB ubiquitination, preventing the release of auxin-responsive factors and leading to an auxin-mimic herbicide-resistant phenotype (LeClere et al. Reference LeClere, Wu, Westra and Sammons2018). These findings suggest that the Colorado populations likely possess a distinct and novel resistance mechanism, which could be an NTSR mechanism or a yet unknown TSR mechanism. In contrast, the dicamba-resistant phenotype observed in the Nebraska kochia population is attributed to the known TSR mechanism, though it may also involve additional mechanisms. While reports of auxin-mimic herbicides target-site resistance mechanisms are relatively limited, NTSR mechanisms to auxin-mimic herbicides have been documented in various studies and are often associated with cross-resistance to other modes of action (Dang et al. Reference Dang, Malone, Boutsalis, Krishnan, Gill and Preston2018; de Figueiredo et al. Reference de Figueiredo, Barnes, Boot, de Figueiredo, Nissen, Dayan and Gaines2022a; Souza et al. Reference Souza, Leal, Montgomery, Ortiz, Simões Araujo, Morran, de Figueiredo, Langaro, Zobiole and Nissen2023).

Figure 9. The top illustration shows the gene structure of the kochia IAA16 gene. The 5′ and 3′ untranslated regions are represented by grey circles, while the exons are shown as blue boxes. The introns are indicated by black lines. The bottom section displays Sanger sequencing chromatograms representing three kochia populations from Colorado classified as dicamba resistant (A5, A22, and A32) and one from Nebraska (NEK 30). The region highlighted within the red rectangle is associated with the dicamba-resistant phenotype (G73N), where sequence GGT is the wild-type allele encoding G, and AAT is the mutant allele encoding N. MF376149.1 was used as the GenBank reference for IAA16 susceptible allele.

While the new sugar beet trait may provide enhanced weed management capabilities, it is imperative to employ alternative herbicides or other weed management strategies during fallow periods rather than relying on dicamba alone. Research has shown that implementing diverse herbicide programs, particularly in conjunction with crop rotations, can be an effective strategy for controlling resistant populations of kochia (Sbatella et al. Reference Sbatella, Adjesiwor, Kniss, Stahlman, Westra, Moechnig and Wilson2019). Therefore, adopting a comprehensive approach to weed management, tailored to the specific field conditions, and considering the resistance history in the area and the weed species present, becomes fundamental.

Glufosinate Resistance Status

Our survey found no glufosinate resistance in any of the weed populations sampled from Colorado, Nebraska, or Wyoming. This includes populations of kochia and Palmer amaranth that exhibited resistance to glyphosate and dicamba (Figures 1C, 2C, and 3C). Although glyphosate and dicamba are used extensively in current weed management systems for sugar beets in the Central Great Plains, glufosinate is not currently included. The current lack of glufosinate use on sugar beet may be due to the availability of more cost-effective preplant herbicides with a broader weed control spectrum. With the introduction of a new sugar beet trait that confers resistance to glufosinate, its use on the crop is expected to increase, particularly with postemergence applications.

To date, 10 cases of herbicide resistance to glufosinate have been documented. Most of them occurred in poaceous species and, recently, in Palmer amaranth (Brunharo et al. Reference Brunharo, Takano, Mallory-Smith, Dayan and Hanson2019; Carvalho-Moore et al. Reference Carvalho-Moore, Norsworthy, González-Torralva, Hwang, Patel, Barber, Butts and McElroy2022; He et al. Reference He, Liu, Chen, Bai, Liao, Bai and Pan2023; Priess et al. Reference Priess, Norsworthy, Godara, Mauromoustakos, Butts, Roberts and Barber2022b). An increase in gene expression and gene amplification is the resistance mechanism in populations of Palmer amaranth from Arkansas (Carvalho-Moore et al. Reference Carvalho-Moore, Norsworthy, González-Torralva, Hwang, Patel, Barber, Butts and McElroy2022). A novel point mutation, S59G, is in contact with important binding residues of glufosinate and was recently reported to confer resistance in a population of goosegrass (Eleusine indica L.) in China (Zhang et al. Reference Zhang, Yu, Han, Yu, Nyporko, Tian, Beckie and Powles2022).

In our study, glufosinate was effective on all species. We emphasize that the plants were treated at an early growth stage (5- to 7-cm height) under controlled conditions in a greenhouse setting. Glufosinate is a contact herbicide that requires appropriate coverage, and the timing of its application is crucial to achieve an effective control. Plant sensitivity to glufosinate varies considerably by species and likely depends on the amount that reaches the target enzyme, glutamine synthetase. For instance, when the same rate of glufosinate was applied to the leaves of grasses (johnsongrass and ryegrass) and broadleaf species (kochia and Palmer amaranth), lower herbicide concentrations were found in grasses. This resulted in reduced glutamine synthetase inhibition and less visual injury (Takano and Dayan Reference Takano and Dayan2020). Kumar et al. (Reference Kumar, Jha and Reichard2014) observed that the efficacy of glufosinate, applied at the same rate as in our study, was least effective among the herbicide treatments for controlling 8- to 10-cm-tall kochia populations, with control levels below 50%. Similarly, Duenk et al. (Reference Duenk, Soltani, Miller, Hooker, Robinson and Sikkema2023) noted that an application of glufosinate provided poor control of common lambsquarters, velvetleaf, and redroot pigweed when they were taller than 5 cm in height, but glufosinate performance increased with the addition of the adjuvant ammonium sulfate.

Environmental conditions directly affect glufosinate performance; specifically, light intensity and low humidity can drastically decrease glufosinate efficacy on weeds (Takano and Dayan Reference Takano and Dayan2020). Colorado, Nebraska, and Wyoming have a continental climate and generally experience relatively low humidity with some fluctuations during the summer. These conditions have direct implications for glufosinate applications. Under dry conditions, the absorption of glufosinate may not be optimal due to a rapid dryness of the droplets, thereby reducing its efficacy (Coetzer et al. Reference Coetzer, Al-Khatib and Loughin2001; Takano and Dayan Reference Takano and Dayan2020).

Implementing an appropriate herbicide program is essential to prolong the effectiveness of glufosinate and ensure the sustainability of the herbicide-resistant sugar beet. Careful consideration should be given to employing a well-designed herbicide strategy, and especially considering the weed species in the area. For instance some weed species may respond differently when glufosinate is applied in a mixture or sequentially, where in some cases, antagonism will likely occur when herbicide combinations are employed. Besançon et al. (Reference Besançon, Penner and Everman2018) noted that when glufosinate and glyphosate were combined to control giant foxtail and velvetleaf there was a significant reduction of glyphosate translocation. The mixture of dicamba and glufosinate was antagonistic, as reflected in poor control and percent mortality in Palmer amaranth populations (Priess et al. Reference Priess, Popp, Norsworthy, Mauromoustakos, Roberts and Butts2022a). In contrast, a synergistic interaction was observed when glufosinate and dicamba were applied to control sicklepod [Senna obtusifolia (L.) Irwin & Barneby] (Joseph et al. Reference Joseph, Marshall and Sanders2018). Glufosinate plus dicamba were shown to have an additive effect on giant ragweed (Ambrosia trifida L.) (Ganie and Jhala Reference Ganie and Jhala2017).

Our survey reveals that resistance to two of the three herbicides (glyphosate and dicamba) to which the new sugar beet trait will confer resistance is already prevalent in sugar beet production areas of Colorado, Nebraska, and Wyoming, even prior to the new trait’s release. This underscores the critical need for proactive stewardship and IWM strategies to preserve the long-term effectiveness of this new technology. Lessons learned from the current sugar beet cropping systems, where overreliance on glyphosate has led to widespread resistance, should guide the development and implementation of diversified weed management programs. Employing alternative herbicide sites-of-action, along with an IWM approach, becomes critical to mitigate the evolution of resistance and preserve the utility of the new sugar beet trait.

Practical Implications

Surveys play a crucial role in the early detection of herbicide resistance, enabling the implementation of effective management strategies. With the impending release of a genetically engineered sugar beet trait that confers resistance to glyphosate, dicamba, and glufosinate, significant changes are expected in weed management practices, particularly in in-crop weed control. Growers associated with the Western Sugar Cooperative, who funded this study, have expressed concerns about the potential widespread resistance to these active ingredients. Although glyphosate resistance in kochia and Palmer amaranth is widespread across the United States, research specifically within sugar beet systems has been limited. This study provides valuable insights into the resistance status and frequency of problematic weed species in current sugar beet systems across Colorado, Nebraska, and Wyoming to the three active ingredients. Additionally, our findings reveal the first occurrence of glyphosate- and dicamba-resistant Palmer amaranth populations in Colorado and dicamba-resistant kochia populations within sugar beet systems in Colorado and Nebraska. Furthermore, we report that all dicamba-resistant kochia populations tested in Colorado lack a known TSR mechanism, suggesting the involvement of a novel resistance mechanism. This study also provides the first assessment of glufosinate resistance in sugar beet weeds in this region. The widespread occurrence of kochia and palmer exhibiting resistance to glyphosate and dicamba in certain areas has direct implications in how those must be managed once the new trait is released. To minimize resistance evolution and safeguard the long-term efficacy of this new technology, it is crucial to implement proactive stewardship practices. Growers should adopt IWM strategies that include crop rotation, using cover crops, employing mechanical weed control, diversifying herbicide sites-of-action, and avoiding repeated use of the same herbicide. Building upon lessons learned from the current sugar beet crop system will be essential to ensure the sustainable success of this new technology.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/wet.2024.77

Acknowledgments

We thank members of the Western Sugar Cooperative for their assistance in identifying field sites and collecting weed seeds.

Funding

This research was supported in part by the Western Sugar Joint Research Committee and by the U.S. Department of Agriculture–National Institute of Food and Agriculture, through Hatch project COL00783 to the Colorado State University Agricultural Experiment Station.

Competing interests

The authors declare none.

Footnotes

Associate Editor: Vipan Kumar, Cornell University

References

Adegas, FS, Correia, NM, da Silva, AF, Concenço, G, Gazziero, DLP, Dalazen, G (2022) Glyphosate-resistant (GR) soybean and corn in Brazil: past, present, and future. Adv Weed Sci 40:e0202200102 Google Scholar
Beckie, HJ, Blackshaw, RE, Hall, LM, Johnson, EN (2016) Pollen-and seed-mediated gene flow in kochia (Kochia scoparia). Weed science 64:624633 Google Scholar
Beckie, HJ, Hall, LM, Shirriff, SW, Martin, E, Leeson, JY (2019) Triple-resistant kochia [Kochia scoparia (L.) Schrad.] in Alberta. Can J Plant Sci 99:281285 Google Scholar
Besançon, TE, Penner, D, Everman, WJ (2018) Reduced translocation is associated with antagonism of glyphosate by glufosinate in giant foxtail (Setaria faberi) and velvetleaf (Abutilon theophrasti). Weed Sci 66:159167 Google Scholar
Bhadra, T, Mahapatra, CK, Paul, SK (2020) Weed management in sugar beet: A review. Fundam Appl Agric 5:147156 Google Scholar
Brunharo, CA, Gast, R, Kumar, V, Mallory-Smith, CA, Tidemann, BD, Beckie, HJ (2022) Western United States and Canada perspective: are herbicide-resistant crops the solution to herbicide-resistant weeds? Weed Sci 70:272286 Google Scholar
Brunharo, CA, Takano, HK, Mallory-Smith, CA, Dayan, FE, Hanson, BD (2019) Role of glutamine synthetase isogenes and herbicide metabolism in the mechanism of resistance to glufosinate in Lolium perenne L. spp. multiflorum biotypes from Oregon. J Agric Food Chem 67:84318440 Google Scholar
Butler-Jones, AL, Maloney, EC, McClements, M, Kramer, WB, Morran, S, Gaines, TA, Besançon, TE, Sosnoskie, LM (2024) Confirmation of glyphosate-resistant Palmer amaranth (Amaranthus palmeri) populations in New York and responses to alternative chemistries. Weed Sci doi: 10.1017/wsc.2024.48 Google Scholar
Carvalho-Moore, P, Norsworthy, JK, González-Torralva, F, Hwang, J-I, Patel, JD, Barber, LT, Butts, TR, McElroy, JS (2022) Unraveling the mechanism of resistance in a glufosinate-resistant Palmer amaranth (Amaranthus palmeri) accession. Weed Sci 70:370379 Google Scholar
Cioni, F, Maines, G (2010) Weed control in sugarbeet. Sugar Tech 12:243255 Google Scholar
Coetzer, E, Al-Khatib, K, Loughin, TM (2001) Glufosinate efficacy, absorption, and translocation in amaranth as affected by relative humidity and temperature. Weed Sci 49:813 Google Scholar
Comont, D, Lowe, C, Hull, R, Crook, L, Hicks, HL, Onkokesung, N, Beffa, R, Childs, DZ, Edwards, R, Freckleton, RP, Neve, P (2020) Evolution of generalist resistance to herbicide mixtures reveals a trade-off in resistance management. Nat Commun 11:3086 Google Scholar
Correia, NM, Durigan, JC (2010) Weed control in glyphosate tolerant soybean crop. Bragantia 69:319327 Google Scholar
Dang, HT, Malone, JM, Boutsalis, P, Krishnan, M, Gill, G, Preston, C (2018) Reduced translocation in 2,4-D-resistant oriental mustard populations (Sisymbrium orientale L.) from Australia. Pest Manag Sci 74:15241532 Google Scholar
de Figueiredo, MRA, Barnes, H, Boot, CM, de Figueiredo, ABTB, Nissen, SJ, Dayan, FE, Gaines, TA (2022a) Identification of a novel 2,4-D metabolic detoxification pathway in 2,4-D-resistant waterhemp (Amaranthus tuberculatus). J Agric Food Chem 70:1538015389 Google Scholar
de Figueiredo, MRA, Küpper, A, Malone, JM, Petrovic, T, de Figueiredo, ABTB, Campagnola, G, Peersen, OB, Prasad, KVSK, Patterson, EL, Reddy, ASN, Kubeš, MF, Napier, R, Dayan, FE, Preston, C, Gaines, TA (2022b) An in-frame deletion mutation in the degron tail of auxin coreceptor IAA2 confers resistance to the herbicide 2,4-D in Sisymbrium orientale . Proc Natl Acad Sci USA 119:e2105819119 Google Scholar
de Figueiredo, MRA, Strader, LC (2022) Intrinsic and extrinsic regulators of Aux/IAA protein degradation dynamics. Trends Biochem Sci 47:865874 Google Scholar
DeGreeff, RD, Varanasi, AV, Dille, JA, Peterson, DE, Jugulam, M (2018) Influence of plant growth stage and temperature on glyphosate efficacy in common lambsquarters (Chenopodium album). Weed Technol 32:448453 Google Scholar
Duenk, E, Soltani, N, Miller, RT, Hooker, DC, Robinson, DE, Sikkema, PH (2023) Influence of glufosinate rate, ammonium sulfate, and weed height on annual broadleaf weed control. J Agric Sci doi: 10.5539/jas.v15n4p7 Google Scholar
Foster, DC, Steckel, LE (2022) Confirmation of dicamba-resistant Palmer amaranth in Tennessee. Weed Technol 36:777780 Google Scholar
Freiman, JA, Chalmers, TC, Smith, HA, Kuebler, RR (2019) The importance of beta, the type II error, and sample size in the design and interpretation of the randomized controlled trial: survey of two sets of “negative” trials. Pages 357389 in Bailar, JC , III, Mostelle, F, eds. Medical Uses of Statistics. Boca Raton, FL: CRC Press Google Scholar
Gaines, TA, Barker, AL, Patterson, EL, Westra, P, Westra, EP, Wilson, RG, Jha, P, Kumar, V, Kniss, AR (2016) EPSPS gene copy number and whole-plant glyphosate resistance level in Kochia scoparia . PLoS One 11:e0168295 Google Scholar
Gaines, TA, Patterson, EL, Neve, P (2019) Molecular mechanisms of adaptive evolution revealed by global selection for glyphosate resistance. New Phytol 223:17701775 Google Scholar
Gaines, TA, Shaner, DL, Ward, SM, Leach, JE, Preston, C, Westra, P (2011) Mechanism of resistance of evolved glyphosate-resistant Palmer amaranth (Amaranthus palmeri). J Agric Food Chem 59:58865889 Google Scholar
Gaines, TA, Slavov, GT, Hughes, D, Küpper, A, Sparks, CD, Oliva, J, Vila-Aiub, MM, Garcia, MA, Merotto, A Jr, Neve, P (2021) Investigating the origins and evolution of a glyphosate-resistant weed invasion in South America. Mol Ecol 30:53605372 Google Scholar
Gaines, TA, Zhang, W, Wang, D, Bukun, B, Chisholm, ST, Shaner, DL, Nissen, SJ, Patzoldt, WL, Tranel, PJ, Culpepper, AS (2010) Gene amplification confers glyphosate resistance in Amaranthus palmeri . Proc Natl Acad Sci USA 107:10291034 Google Scholar
Ganie, ZA, Jhala, AJ (2017) Interaction of 2,4-D or dicamba with glufosinate for control of glyphosate-resistant giant ragweed (Ambrosia trifida L.) in glufosinate-resistant maize (Zea mays L.). Front Plant Sci 8:1207 Google Scholar
Geddes, CM, Owen, ML, Ostendorf, TE, Leeson, JY, Sharpe, SM, Shirriff, SW, Beckie, HJ (2022) Herbicide diagnostics reveal multiple patterns of synthetic auxin resistance in kochia (Bassia scoparia). Weed Technol 36:2837 Google Scholar
Geddes, CM, Pittman, MM, Gulden, RH, Jones, T, Leeson, JY, Sharpe, SM, Shirriff, SW, Beckie, HJ (2021) Rapid increase in glyphosate resistance and confirmation of dicamba-resistant kochia (Bassia scoparia) in Manitoba. Can J Plant Sci 102:459464 Google Scholar
Gerhards, R, Bezhin, K, Santel, H-J (2017) Sugar beet yield loss predicted by relative weed cover, weed biomass and weed density. Plant Protect Sci 53:118125 Google Scholar
Ghanizadeh, H, Buddenhagen, CE, Harrington, KC, James, TK (2019) The genetic inheritance of herbicide resistance in weeds. Crit Rev Plant Sci 38:295312 Google Scholar
Ghanizadeh, H, He, L, Griffiths, AG, Harrington, KC, Carbone, V, Wu, H, Tian, K, Bo, H, Xinhui, D (2024) A novel mutation in IAA16 is associated with dicamba resistance in Chenopodium album . Pest Manag Sci 80:36753683 Google Scholar
Giacomini, DA, Westra, P, Ward, SM (2019) Variable inheritance of amplified EPSPS gene copies in glyphosate-resistant Palmer amaranth (Amaranthus palmeri). Weed Sci 67:176182 Google Scholar
Godar, AS, Stahlman, PW, Jugulam, M, Dille, JA (2015) Glyphosate-resistant kochia (Kochia scoparia) in Kansas: EPSPS gene copy number in relation to resistance levels. Weed Sci 63:587595 Google Scholar
He, S, Liu, M, Chen, W, Bai, D, Liao, Y, Bai, L, Pan, L (2023) Eleusine indica cytochrome P450 and glutathione S-transferase are linked to high-level resistance to glufosinate. J Agric Food Chem 71:1424314250 Google Scholar
Heap, I (2024) The international herbicide-resistant weed database. http://www.weedscience.org/. Accessed: May 23, 2024Google Scholar
Huang, Z, Zhou, X, Zhang, C, Jiang, C, Huang, H, Wei, S (2020) First report of molecular basis of resistance to imazethapyr in common lambsquarters (Chenopodium album). Weed Sci 68:6368 Google Scholar
Jhala, AJ, Norsworthy, JK, Ganie, ZA, Sosnoskie, LM, Beckie, HJ, Mallory-Smith, CA, Liu, J, Wei, W, Wang, J, Stoltenberg, DE (2020) Pollen-mediated gene flow and transfer of resistance alleles from herbicide-resistant broadleaf weeds. Weed Technol 35:173187 Google Scholar
Jones, EA, Dunne, JC, Cahoon, CW, Jennings, KM, Leon, RG, Everman, WJ (2024) Confirmation and inheritance of glufosinate resistance in an Amaranthus palmeri population from North Carolina. Plant Environ Interact 5:e10154 Google Scholar
Joseph, DD, Marshall, MW, Sanders, CH (2018) Efficacy of 2,4-D, dicamba, glufosinate and glyphosate combinations on selected broadleaf weed heights. Am J Plant Sci 9:13211333 Google Scholar
Jugulam, M, Niehues, K, Godar, AS, Koo, D-H, Danilova, T, Friebe, B, Sehgal, S, Varanasi, VK, Wiersma, A, Westra, P (2014) Tandem amplification of a chromosomal segment harboring 5-enolpyruvylshikimate-3-phosphate synthase locus confers glyphosate resistance in Kochia scoparia . Plant Physiol 166:12001207 Google Scholar
Jursík, M, Holec, J, Soukup, J, Venclová, V (2008) Competitive relationships between sugar beet and weeds in dependence on time of weed control. Plant Soil Environ 54:108116 Google Scholar
Keith, BK, Kalinina, EB, Dyer, WE (2011) Differentially expressed genes in dicamba-resistant and dicamba-susceptible biotypes. Weed Biol Manag 11:224234 Google Scholar
Khan, MF (2010) Introduction of glyphosate-tolerant sugar beet in the United States. Outlooks Pest Manag 21:3841 Google Scholar
Kniss, AR (2018) Genetically engineered herbicide-resistant crops and herbicide-resistant weed evolution in the United States. Weed Sci 66:260273 Google Scholar
Kumar, V, Engel, RP, Currie, R, Jha, P, Stahlman, PW, Thompson, C (2019b) Dicamba-resistant kochia (Bassia scoparia) in Kansas: characterization and management with fall-or spring-applied PRE herbicides. Weed Technol 33:342348 Google Scholar
Kumar, V, Jha, P (2015) Influence of herbicides applied postharvest in wheat stubble on control, fecundity, and progeny fitness of Kochia scoparia in the US Great Plains. Crop Prot 71:144149 Google Scholar
Kumar, V, Jha, P, Jugulam, M, Yadav, R, Stahlman, PW (2019a) Herbicide-resistant kochia (Bassia scoparia) in North America: a review. Weed Sci 67:415 Google Scholar
Kumar, V, Jha, P, Reichard, N (2014) Occurrence and characterization of kochia (Kochia scoparia) accessions with resistance to glyphosate in Montana. Weed Technol 28:122130 Google Scholar
Kumar, V, Liu, R, Stahlman, PW (2020) Differential sensitivity of Kansas Palmer amaranth populations to multiple herbicides. Agron J 112:21522163 Google Scholar
Leal, JF, Souza, AdS, Borella, J, Araujo, ALS, Langaro, AC, Chapeta, AC, Amorim, ES, Silva, GS, Morran, S, Zobiole, LHS, Gaines, TA, Pinho, CF (2022) Sumatran fleabane (Conyza sumatrensis) resistant to PSI-inhibiting herbicides and physiological responses to paraquat. Weed Sci 70:4654 Google Scholar
LeClere, S, Wu, C, Westra, P, Sammons, RD (2018) Cross-resistance to dicamba, 2,4-D, and fluroxypyr in Kochia scoparia is endowed by a mutation in an AUX/IAA gene. Proc Natl Acad Sci USA 115:E2911E2920 Google Scholar
Lueck, AB, Peters, TJ, Khan, M, Boetel, MA (2017) Survey of weed control and production practices on sugarbeet in Minnesota and eastern North Dakota in 2016. Sugarbeet Res Rep 47:717. Fargo: North Dakota State University Sugarbeet Research & Education BoardGoogle Scholar
Martin, SL, Benedict, L, Wei, W, Sauder, CA, Beckie, HJ, Hall, LM (2020) High gene flow maintains genetic diversity following selection for high EPSPS copy number in the weed kochia (Amaranthaceae). Sci Rep 10:18864 Google Scholar
McKenzie-Gopsill, A, Graham, G, Laforest, M, Ibarra, S, Hann, S, Wagg, C (2020) Occurrence and management of PSII-inhibitor-resistant Chenopodium album L. in Atlantic Canadian potato production. Agronomy 10:1369 Google Scholar
Moghadam, SH, Alebrahim, MT, Mohebodini, M, Macgregor, D (2023) Genetic variation of Amaranthus retroflexus L. and Chenopodium album L. (Amaranthaceae) suggests multiple independent introductions into Iran. Front Plant Sci 13:1024555 Google Scholar
Montgomery, JS, Soni, N, Marques Hill, S, Morran, S, Patterson, E, Edwards, S, Ratnayake, S, Hung, Y-H, Pandesha, PH, Slotkin, RK (2024) A transposable element insertion in IAA16 interrupts normal splicing and generates a novel dicamba resistance allele in Bassia scoparia. bioRxiv doi: 10.1101/2024.07.19.604363 Google Scholar
Morishita, DW (2018) Impact of glyphosate-resistant sugar beet. Pest Manag Sci 74:10501053 Google Scholar
Murphy, BP, Tranel, PJ (2019) Target-site mutations conferring herbicide resistance. Plants 8:382 Google Scholar
Nowacki, A (2017) Chi-square and Fisher’s exact tests. Cleve Clin J Med 84:e205 Google Scholar
Ou, J, Thompson, CR, Stahlman, PW, Jugulam, M (2018a) Preemergence application of dicamba to manage dicamba-resistant kochia (Kochia scoparia). Weed Technol 32:309313 Google Scholar
Ou, J, Thompson, CR, Stahlman, PW, Bloedow, N, Jugulam, M (2018b) Reduced translocation of glyphosate and dicamba in combination contributes to poor control of Kochia scoparia: evidence of herbicide antagonism. Sci Rep 8:111 Google Scholar
Owen, MJ, Walsh, MJ, Llewellyn, RS, Powles, SB (2007) Widespread occurrence of multiple herbicide resistance in Western Australian annual ryegrass (Lolium rigidum) populations. Aust J Agric Res 58:711718 Google Scholar
Patterson, EL, Saski, CA, Sloan, DB, Tranel, PJ, Westra, P, Gaines, TA (2019) The draft genome of Kochia scoparia and the mechanism of glyphosate resistance via transposon-mediated EPSPS tandem gene duplication. Genome Biol Evol 11:29272940 Google Scholar
Preston, C, Belles, DS, Westra, PH, Nissen, SJ, Ward, SM (2009) Inheritance of resistance to the auxinic herbicide dicamba in kochia (Kochia scoparia). Weed Sci 57:4347 Google Scholar
Priess, GL, Norsworthy, JK, Godara, N, Mauromoustakos, A, Butts, TR, Roberts, TL, Barber, T (2022b) Confirmation of glufosinate-resistant Palmer amaranth and response to other herbicides. Weed Technol 36:368372 Google Scholar
Priess, GL, Popp, MP, Norsworthy, JK, Mauromoustakos, A, Roberts, TL, Butts, TR (2022a) Optimizing weed control using dicamba and glufosinate in eligible crop systems. Weed Technol 36:468480 Google Scholar
R Core Team (2021) R: A language and Environmwent for Statistical Computing. Vienna, Austria: R Foundation for Statistical Computing. http://www.R-projectorg. Accessed: June 15, 2021Google Scholar
Rahman, A, James, T, Trolove, M (2014) Characteristics and control of dicamba-resistant common lambsquarters (Chenopodium album). Weed Biol Manag 14:8898 Google Scholar
Rigon, CAG, Cutti, L, Turra, GM, Ferreira, EZ, Menegaz, C, Schaidhauer, W, Dayan, FE, Gaines, TA, Merotto A Jr (2023) Recurrent selection of Echinochloa crus-galli with a herbicide mixture reduces progeny sensitivity. J Agric Food Chem 71:68716881 Google Scholar
Sarangi, D, Jhala, AJ (2018) A statewide survey of stakeholders to assess the problem weeds and weed management practices in Nebraska. Weed Technol 32:642655 Google Scholar
Sbatella, GM, Adjesiwor, AT, Kniss, AR, Stahlman, PW, Westra, P, Moechnig, M, Wilson, RG (2019) Herbicide options for glyphosate-resistant kochia (Bassia scoparia) management in the Great Plains. Weed Technol 33:658663 Google Scholar
Schmittgen, TD, Livak, KJ (2008) Analyzing real-time PCR data by the comparative CT method. Nat Protoc 3:11011108 Google Scholar
Schuster, CL, Shoup, DE, Al-Khatib, K (2007) Response of common lambsquarters (Chenopodium album) to glyphosate as affected by growth stage. Weed Sci 55:147151 Google Scholar
Sharpe, SM, Leeson, JY, Geddes, CM, Willenborg, CJ, Beckie, HJ (2023) Survey of glyphosate- and dicamba-resistant kochia (Bassia scoparia) in Saskatchewan. Can J Plant Sci 103:472480 Google Scholar
Singh, V, Etheredge, L, McGinty, J, Morgan, G, Bagavathiannan, M (2020) First case of glyphosate resistance in weedy sunflower (Helianthus annuus). Pest Manag Sci 76:36853692 Google Scholar
Sivesind, EC, Gaska, JM, Jeschke, MR, Boerboom, CM, Stoltenberg, DE (2011) Common lambsquarters response to glyphosate across environments. Weed Technol 25:4450 Google Scholar
Soltani, N, Dille, JA, Robinson, DE, Sprague, CL, Morishita, DW, Lawrence, NC, Kniss, AR, Jha, P, Felix, J, Nurse, RE (2018) Potential yield loss in sugar beet due to weed interference in the United States and Canada. Weed Technol 32:749753 Google Scholar
Sosnoskie, LM, Webster, TM, Kichler, JM, MacRae, AW, Grey, TL, Culpepper, AS (2012) Pollen-mediated dispersal of glyphosate-resistance in Palmer amaranth under field conditions. Weed Sci 60:366373 Google Scholar
Souza, AdS, Leal, JFL, Montgomery, JS, Ortiz, MF, Simões Araujo, AL, Morran, S, de Figueiredo, MRA, Langaro, AC, Zobiole, LHS, Nissen, SJ (2023) Nontarget-site resistance due to rapid physiological response in 2,4-D resistant Conyza sumatrensis: reduced 2,4-D translocation and auxin-induced gene expression. Pest Manag Sci 79:35813592 Google Scholar
Takano, HK, Dayan, FE (2020) Glufosinate-ammonium: a review of the current state of knowledge. Pest Manag Sci 76:39113925 Google Scholar
Todd, OE, Patterson, EL, Westra, EP, Nissen, SJ, Araujo, ALS, Kramer, WB, Dayan, FE, Gaines, TA (2024) Enhanced metabolic detoxification is associated with fluroxypyr resistance in Bassia scoparia . Plant Direct 8:e560 Google Scholar
[USDA] U.S. Department of Agriculture (2023) Crop Production Annual Summary. https://usda.library.cornell.edu/concern/publications/k3569432s. Accessed: May 23, 2024Google Scholar
Van Wychen, L (2016) Survey of the most common and troublesome weeds in broadleaf crops, fruits & vegetables in the United States and Canada. http://wssa.net/wp-content/uploads/2016_Weed_Survey_Final.xlsx. Accessed: May 23, 2024Google Scholar
Vieira, BC, Samuelson, SL, Alves, GS, Gaines, TA, Werle, R, Kruger, GR (2018) Distribution of glyphosate-resistant Amaranthus spp. in Nebraska. Pest Manag Sci 74:23162324 Google Scholar
Ward, SM, Webster, TM, Steckel, LE (2013) Palmer amaranth (Amaranthus palmeri): a review. Weed Technol 27:1227 Google Scholar
Werle, R, Sandell, LD, Buhler, DD, Hartzler, RG, Lindquist, JL (2014) Predicting emergence of 23 summer annual weed species. Weed Sci 62:267279 Google Scholar
Westra, EP, Nissen, SJ, Getts, TJ, Westra, P, Gaines, TA (2019) Survey reveals frequency of multiple resistance to glyphosate and dicamba in kochia (Bassia scoparia). Weed Technol 33:664672 Google Scholar
Wickham, H (2016) ggplot2: Elegant Graphics for Data Analysis. New York: Springer-Verlag Google Scholar
Wiersma, AT, Gaines, TA, Preston, C, Hamilton, JP, Giacomini, D, Robin Buell, C, Leach, JE, Westra, P (2015) Gene amplification of 5-enol-pyruvylshikimate-3-phosphate synthase in glyphosate-resistant Kochia scoparia . Planta 241:463474 Google Scholar
Yanniccari, M, Palma-Bautista, C, Vázquez-García, JG, Gigon, R, Mallory-Smith, CA, De Prado, R (2023) Constitutive overexpression of EPSPS by gene duplication is involved in glyphosate resistance in Salsola tragus . Pest Manag Sci 79:10621068 Google Scholar
Yerka, MK, Wiersma, AT, Lindenmayer, RB, Westra, P, Johnson, WG, de Leon, N, Stoltenberg, DE (2013) Reduced translocation is associated with tolerance of common lambsquarters (Chenopodium album) to glyphosate. Weed Sci 61:353360 Google Scholar
Zhang, C, Yu, Q, Han, H, Yu, C, Nyporko, A, Tian, X, Beckie, H, Powles, S (2022) A naturally evolved mutation (Ser59Gly) in glutamine synthetase confers glufosinate resistance in plants. J Exp Bot 73:22512262 Google Scholar
Figure 0

Figure 1. Geo-referenced map illustrating the Bassia scoparia (kochia) populations collected in Colorado during fall 2021. The dots on the map represent the locations of kochia populations, and their color signifies their response to glyphosate treatment (A), dicamba (B), and glufosinate (C). On the left a map illustrates the distribution of the populations in a state overview. On the right, a close-up map focuses on the main counties where the samples were collected. Populations classified as resistant (>20% survival) are represented by red dots, yellow dots indicate low frequency (1% to 19% survival), and green dots represent susceptible populations (0% survival).

Figure 1

Figure 2. Geo-referenced map illustrating the Bassia scoparia (kochia) populations collected in Nebraska during fall 2020. The dots on the map represent the locations of kochia populations, and their color signifies their response to glyphosate treatment (A), dicamba (B), and glufosinate (C). On the left, a map illustrates the distribution of the populations in a state overview. On the right, a close-up map focuses on the main counties where the samples were collected. Populations classified as resistant (>20% survival) are represented by red dots, yellow dots indicate low frequency (1% to 19% survival), and green dots represent susceptible populations (0% survival).

Figure 2

Figure 3. Geo-referenced map illustrating the Bassia scoparia (kochia) populations collected in Wyoming during fall 2020. The dots on the map represent the locations of kochia populations, and their color signifies their response to glyphosate treatment (A), dicamba (B), and glufosinate (C). On the left, a map illustrates the distribution of the populations in a state overview. On the right, a close-up map focuses on the main counties where the samples were collected, including the highlighted blue squares where a few samples were collected in southeastern Wyoming. Populations classified as resistant (>20% survival) are represented by red dots, yellow dots indicate low frequency (1% to 19% survival), and green dots represent susceptible populations (0% survival).

Figure 3

Figure 4. Frequency of observed phenotypes of kochia (left) and Palmer amaranth (right) populations collected from Colorado, Nebraska and Wyoming during fall 2020 and 2021, following treatment in a greenhouse setting with glyphosate, dicamba, and glufosinate. Bar colors represent the phenotype characterization: green (dashed to the right) represent susceptible populations (0% survival), yellow represents low resistance (1% to 19% survival), and red (dashed to the left) represent populations classified as resistant (>20% survival).

Figure 4

Figure 5. Relative EPSPS gene copy number in kochia populations collected from Colorado. The green and red bars represent the sensitive and resistant references (Sen and Res), respectively. The blue bars labeled as A represent resistant populations (>20% survival) surveyed from Colorado. Each bar represents the mean of the relative EPSPS copy number from three biological replicates (shown as grey circles) within each population, with error bars indicating the standard deviation.

Figure 5

Figure 6. Relative EPSPS gene copy number in kochia populations collected from Nebraska and Wyoming. The green and red bars represent the sensitive and resistant references (Sen and Res), respectively. The blue bars labeled as NEK represent Nebraska kochia populations, and WYK represents Wyoming kochia populations. Each bar represents the mean of the relative EPSPS copy number from three biological replicates (shown as grey circles) within each population, with error bars indicating the standard deviation.

Figure 6

Figure 7. Relative EPSPS gene copy number in Palmer amaranth populations collected from Colorado and Nebraska. Known sensitive (Sen) and resistant (Res) Palmer amaranth populations were used as positive and negative controls. The blue bars labeled as COP represent Colorado Palmer amaranth populations classified as resistant (>20% survival), while the blue bar labeled as NEP represents a Nebraska Palmer amaranth population. Each bar represents the mean and standard deviation of the Relative EPSPS copy number from three biological replicates (shown as grey circles) within each population.

Figure 7

Figure 8. Matrix heatmaps of glyphosate and dicamba resistance in kochia populations across Colorado (A), Nebraska (B), and Wyoming (C). Heatmaps show the frequency of kochia populations categorized by phenotypic classifications (susceptible, low resistant, and resistant) to glyphosate and dicamba in Colorado, Nebraska, and Wyoming. The colors represent the number of observations in each category, with darker shades indicating higher frequencies. A Fisher’s exact test was performed to assess the statistical significance of associations between glyphosate and dicamba resistance. The test statistics and P-values are displayed within each heatmap. Associations are considered significant if the P-value is < 0.05.

Figure 8

Figure 9. The top illustration shows the gene structure of the kochia IAA16 gene. The 5′ and 3′ untranslated regions are represented by grey circles, while the exons are shown as blue boxes. The introns are indicated by black lines. The bottom section displays Sanger sequencing chromatograms representing three kochia populations from Colorado classified as dicamba resistant (A5, A22, and A32) and one from Nebraska (NEK 30). The region highlighted within the red rectangle is associated with the dicamba-resistant phenotype (G73N), where sequence GGT is the wild-type allele encoding G, and AAT is the mutant allele encoding N. MF376149.1 was used as the GenBank reference for IAA16 susceptible allele.

Supplementary material: File

Simões Araujo et al. supplementary material

Simões Araujo et al. supplementary material
Download Simões Araujo et al. supplementary material(File)
File 3.9 MB