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Ecological, evolutionary, and management implications of sugar beet cropping systems with three transgenic herbicide-resistance traits

Published online by Cambridge University Press:  12 March 2025

Het Samir Desai Open the ORCID record for Het Samir Desai [Opens in a new window] ,
Fabian Menalled ,
Todd A. Gaines  and
Lovreet S. Shergill
Het Samir Desai*
Affiliation:
Ph.D Student, Montana State University–Bozeman, Southern Agricultural Research Center, Huntley, MT, USA
Fabian Menalled
Affiliation:
Professor, Department of Land Resources and Environmental Sciences, Montana State University, Bozeman, MT, USA
Todd A. Gaines
Affiliation:
Associate Professor, Department of Agricultural Biology, Colorado State University, Fort Collins, CO, USA
Lovreet S. Shergill
Affiliation:
Assistant Professor, Montana State University, Southern Agricultural Research Center, Huntley, MT, USA Assistant Professor, Department of Agricultural Biology, Colorado State University, Fort Collins, CO, USA
*
Corresponding author: Het Samir Desai; Email: het.desai@student.montana.edu
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Abstract

The commercialization of a three-way transgenic sugar beet cultivar, engineered for resistance to glyphosate, glufosinate, and dicamba (hereafter referred to as “triple-stacked”) is anticipated by the mid-2020s. While offering potential benefits for growers facing glyphosate resistance, two of three herbicides (dicamba and glyphosate) to be utilized with triple-stacked sugar beet (Beta vulgaris L.) have previously been used on major weeds in western U.S. cropping systems, raising concerns about preexisting resistance to these active ingredients. We conducted a field survey in sugar beet–growing counties of southeast Montana and northwest Wyoming in fall 2021, before the sugar beet harvest. We collected kochia [Bassia scoparia (L.) A.J. Scott], redroot pigweed (Amaranthus retroflexus L.), and common lambsquarters (Chenopodium album L.) populations and screened them for glyphosate, glufosinate, and dicamba resistance in greenhouse conditions. Our results showed two-way resistance (glyphosate and dicamba) in 32% of B. scoparia populations and reduced susceptibility to glyphosate in 78% of C. album populations. Additionally, we conducted a greenhouse experiment to assess the emergence patterns of collected populations. Phylogenetically closely related B. scoparia and C. album showed higher resemblance in emergence pattern than the distant relative A. retroflexus. While the majority of B. scoparia and C. album populations emerged in <20 d (time required to reach 90% emergence [E90] < 20 d], A. retroflexus populations required >30 d to reach E90. Widespread glyphosate and dicamba resistance in B. scoparia populations raises concerns about the long-term feasibility of a triple-stacked sugar beet cultivar. Furthermore, the delayed emergence of A. retroflexus may enable it to evade early-season weed management.

Keywords

Amaranthus retroflexusBassia scopariaChenopodium albumdicambaemergence dynamicsglyphosateglufosinatephylogenetic niche conservatism

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Type
Research Article
Information
Weed Science , Volume 73 , 2025 , e39
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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.
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© The Author(s), 2025. Published by Cambridge University Press on behalf of Weed Science Society of America

Introduction

Genetically modified herbicide-resistant crop cultivars have been widely adopted since shortly after commercialization, covering 71.5 million ha in the United States alone (Brunharo et al. Reference Brunharo, Gast, Kumar, Mallory-Smith, Tidemann and Beckie2022). These crop cultivars facilitated consistent and improved weed management, enhanced crop safety, and promoted no-till farming for increased soil and water conservation (Duke Reference Duke2015; Green Reference Green2012). However, the widespread adoption of herbicide-resistant cultivars has led to a reduction in the diversity of herbicide usage and other nonchemical weed management tactics (Beckie and Hall Reference Beckie and Hall2014; Brunharo et al. Reference Brunharo, Gast, Kumar, Mallory-Smith, Tidemann and Beckie2022; Duke Reference Duke2012). As a consequence, weed management protocols have become monotonous, relying on a single or a few sites of action (Brunharo et al. Reference Brunharo, Gast, Kumar, Mallory-Smith, Tidemann and Beckie2022; Mortensen et al. Reference Mortensen, Ryan and Smith2024). Repeated applications of the same site of action exert selective pressure on weed populations and ultimately result in the selection of herbicide-resistant biotypes (Heap Reference Heap2014; Mortensen et al. Reference Mortensen, Ryan and Smith2024; Vencill et al. Reference Vencill, Nichols, Webster, Soteres, Mallory-Smith, Burgos, Johnson and McClelland2012), including many cases of multiple herbicide resistance (Bagavathiannan and Davis Reference Bagavathiannan and Davis2018; Menalled et al. Reference Menalled, Peterson, Smith, Curran, Páez and Maxwell2016). For example, worldwide, more than 534 unique cases of herbicide resistance have been identified across 273 weed species, with more than 100 of those species showing multiple herbicide resistance (Heap Reference Heap2025).

Presently, glyphosate-resistant crops in the United States encompass 95% of soybean [Glycine max (L.) Merr.], 70% of cotton (Gossypium hirsutum L.) and corn (Zea mays L.), and 100% of sugar beet (Beta vulgaris L.) cultivation (Beckie and Hall Reference Beckie and Hall2014; McGinnis et al. Reference McGinnis, Meyer and Smith2010). Within the Northern Great Plains, herbicide-resistant alfalfa (Medicago sativa L.), corn, canola (Brassica napus L.), and sugar beet are regularly cultivated. Among these crops, the most commonly prevalent trait is glyphosate resistance, colloquially referred to as Roundup Ready® (Dill Reference Dill2005). Glyphosate-resistant sugar beet was first commercialized in 2008 in the United States after being deregulated in 2005 (Morishita Reference Morishita2018). Before the commercialization of glyphosate-resistant sugar beet, no effective herbicide without crop phytotoxicity was labeled for satisfactory weed management (Morishita Reference Morishita2018). Glyphosate usage has also increased approximately 10-fold in the past 15 yr with the enhanced adoption of glyphosate-resistant sugar beet and other crop cultivars (USGS 2023). As a result, there has been a notable upsurge in the selection of glyphosate-resistant weeds, increasing from 2 to 48 species in two decades (Heap Reference Heap2025), thus threatening the sustainability of this technology.

Due to the widespread prevalence of glyphosate-resistant weed populations, there has been a significant push toward developing two- or three-way herbicide-resistant crop cultivars using gene-stacking techniques (Thornby et al. Reference Thornby, Werth, Hereward, Keenan and Chauhan2018). In the short term, these genetically modified cultivars may enable the use of multiple herbicide sites of action, a practice previously avoided due to the risk of phytotoxicity (Gressel et al. Reference Gressel, Gassmann and Owen2017; James Reference James2010; Manalil et al. Reference Manalil, Werth, Jackson, Hereward, Thornby, Charles, Cook, Chauhan and Preston2015). However, while cultivars with stacked traits increase herbicide diversity, the propensity of weeds to evolve multiple herbicide resistance impedes their long-term utilization (Menalled et al. Reference Menalled, Peterson, Smith, Curran, Páez and Maxwell2016). Therefore, the sustainable adoption of cultivars with stacked traits demands careful consideration, including the current herbicide-resistance status in weeds, crop rotations, application of herbicide mixtures and labeled rates, and integration of nonchemical weed management approaches (Beckie and Hall Reference Beckie and Hall2014; Gressel et al. Reference Gressel, Gassmann and Owen2017). A three-way (glyphosate-, glufosinate-, and dicamba-resistant) transgenic sugar beet cultivar (hereafter referred to as “triple-stacked”) is expected to be commercialized by 2027. Two of the three herbicide (glyphosate and dicamba) sites of action have been extensively used for decades and account for more than half of the overall herbicide market in the United States (Beckie and Hall Reference Beckie and Hall2014; Duke Reference Duke2012). Hence, the current herbicide selection pressure, coupled with the presence of multiple herbicide-resistant biotypes, raises questions about the utility of these cultivars even before their release (Mortensen et al. Reference Mortensen, Ryan and Smith2024).

A cross-pollinated kochia [Bassia scoparia (L.) A.J. Scott] and two self-pollinated weed species (common lambsquarters [Chenopodium album L.] and redroot pigweed [Amaranthus retroflexus L.]) are often seen to survive early-season weed management (e.g., herbicide and preplant tillage) in the Northern Great Plains. Besides herbicide resistance, intraspecific shifts and interspecific differences in emergence could play a significant role in enabling weed species to escape or survive early-season weed management, potentially determining the success or failure of triple-stacked sugar beet. As an evolutionary trait maintained through stabilizing selection, weed emergence may be phylogenetically conserved, influencing long-term management decisions. For example, previous studies have documented bet-hedging adaptation in weed emergence patterns due to constant selective pressure to avoid local extinction (Davis et al. Reference Davis, Clay, Cardina, Dille, Forcella, Lindquist and Sprague2013; Schutte et al. Reference Schutte, Regnier and Harrison2012). Considering the economic significance of sugar beet cultivation (Soltani et al. Reference Soltani, Dille, Robinson, Sprague, Morishita, Lawrence, Kniss, Jha, Felix and Nurse2018), it is crucial to jointly evaluate the current herbicide-resistance status and the shifts in emergence patterns of these weed species before adopting triple-stacked sugar beet.

To assess the feasibility of a triple-stacked cultivar, we conducted two complementary field and greenhouse studies. First, we performed a late-season survey of the spread and abundance of herbicide resistance in three dominant species: B. scoparia, A. retroflexus, and C. album across sugar beet–growing counties of southeastern (SE) Montana and northwestern (NW) Wyoming. Second, we complemented our survey with an evaluation of the emergence patterns of the target weed species. These two studies allowed us to (1) quantify the occurrence of glyphosate, glufosinate, and dicamba resistance in B. scoparia, A. retroflexus, and C. album populations in SE Montana and NW Wyoming; and (2) evaluate the underlying attributes enabling these species to evade early-season management. Our research questions were (1) How do the frequency and spread of herbicide resistance differ between tested weed species? (2) Is there any correlation between phylogenetic distance and the emergence pattern of tested weed species? (3) Which evolutionary adaptation could contribute to the escape of tested weed species from early-season management in sugar beet? Based on these questions, we hypothesized that (1) the frequency and spread of herbicide resistance differ between self-pollinated and cross-pollinated weed species, (2) weed emergence pattern is a phenological trait that phylogenetically closely related species have conserved during the evolutionary process, and (3) the escape of weed species from early-season management in sugar beet could be attributed to the dual evolutionary adaptations of herbicide resistance plus delayed and/or extended emergence.

Materials and Methods

Field Survey

A field survey was conducted before the sugar beet harvest in SE Montana (Big Horn, Carbon, Custer, Rosebud, Stillwater, Treasure, and Yellowstone counties) and NW Wyoming in August 2021 (Big Horn, Hot Springs, Park, and Washakie counties) (Figure 1A). Before the survey, the coordinates of sugar beet fields were acquired from local agronomists and loaded into a handheld GPS device (Garmin GPSmap® 76C, Olathe, KS, USA). The northernmost sugar beet field (46.299637°N, 107.226228°W) was visited first, and weed populations were collected from adjacent sugar beet fields every 8 km. If no sugar beet field was found at the 8-km mark, weed populations were collected from the nearest sugar beet field. The agronomists also indicated fields with suspected herbicide resistance; therefore, weed populations were collected from these fields, even if they did not fall within the survey design. This systematic collection approach enabled us to sample across the survey area, capturing a representative distribution of weed populations without excessive sampling. Based on the infestation level, the occurrence of weed populations was visually classified into four different categories within each field: (A) weed-free (i.e., no visible weeds; Figure 2A), (B) isolated (i.e., singular plant in 5-m diameter; Figure 2B), (C) clustered (i.e., multiple plants in 5-m diameter; Figure 2C), and (D) widespread (i.e., plants were spread across the field; Figure 2D).

Figure 1.

Infestation pattern of the weed species during an August 2021 survey within the sugar beet cropping systems in southeast Montana and northwest Wyoming: (A) surveyed counties highlighted in orange; (B) number of weed species present (species richness); infestation level and spatial pattern of (C) Bassia scoparia; (D) Amaranthus retroflexus; and (E) Chenopodium album.

Figure 2.

Categories of sugar beet fields based on weed infestation visually identified during a survey conducted in southeast Montana and northwest Wyoming counties: (A) weed-free, (B) isolated, (C) clustered, and (D) widespread. Black arrows indicate isolated and clustered infestations of weeds.

Seed Collection and Storage

The seeds of three major weed species, B. scoparia, A. retroflexus, and C. album, and three minor species, wild oats (Avena fatua L.), green foxtail [Setaria viridis (L.) P. Beauv.], and barnyardgrass [Echinochloa crus-galli (L.) P. Beauv.], were collected by detaching inflorescences with a pruning shear and placing them in paper bags. Major and minor species were classified based on their abundance and impact. For each weed species, seeds were collected from at least 2 to 30 individuals within fields and along the field margins. Seeds collected from fields and margins were kept in separate bags. Seeds from each individual within a population were bulked to achieve a representative seed lot. All within-field collections were conducted leaving ≥50 m from field margins. While seeds were collected by walking in a zigzag pattern across the sugar beet fields for weed populations that showed a clustered and widespread dispersal, a targeted collection was used for isolated populations. Seed bags were kept in a hot-air oven at 35 C for a week to prevent mold development due to excessive moisture. Mature seeds were threshed, cleaned, and stored in paper bags at 15 to 17 C in dark conditions for ∼1 to 2 yr at the greenhouse facility of Southern Agricultural Research Center (SARC), Huntley, MT, until use.

Glyphosate, Glufosinate, and Dicamba Screening

To answer our first question, all herbicide screenings were conducted in a greenhouse at SARC, Huntley, MT, from July 2022 to August 2023. Seeds of B. scoparia, A. retroflexus, C. album, A. fatua, S. viridis, and E. crus-galli populations were individually sown on the surface of thermoformed trays (53 by 28 cm, 1020 Heavy duty, CN-FLHD-X1, Greenhouse Megastore, Danville, IL, USA) filled with potting mix (Pro-Mix BX, Premier Tech Home and Garden, Quakertown, Pennsylvania, USA). Seedlings of individual populations, upon emergence, were transplanted into plastic trays (53 by 28 cm) containing 32 subunits, with one seedling per subunit and one species per tray. In addition, seeds of B. scoparia, A. retroflexus, and C. album susceptible to glyphosate, dicamba, and glufosinate were sown and transplanted following the method described earlier. The seedlings were irrigated daily and fertilized weekly (Miracle-Gro® water-soluble fertilizer [24N-8P-16K], Scotts Miracle-Gro Products, Marysville, OH, USA). Throughout the study, the greenhouse was maintained at 25/20 ± 2 C day/night and a 16/8-h photoperiod. These conditions closely mimic the environmental characteristics of SE Montana and NW Wyoming during late May and early June, which is the usual time frame for the first herbicide application.

Individual trays were treated with either glyphosate (Roundup PowerMax®, Bayer CropScience, St Louis, MO, USA), glufosinate (Liberty® 280 SL, BASF, Research Triangle Park, NC, USA), or dicamba (Clash®, Nufarm American, Alsip, IL, USA) to assess herbicide resistance. Herbicides were uniformly applied to 5- to 10-cm-tall seedlings using a stationary spray cabinet (Research Track Sprayer, De Vries Manufacturing, Hollandale, MN, USA) calibrated to deliver 187 L ha−1 through flat-fan nozzles (TeeJet® XR 8002VS, Spraying System, Wheaton, IL, USA). Given the documented existence of resistance (Hall et al. Reference Hall, Beckie, Low, Shirriff, Blackshaw, Kimmel and Neeser2014; Kumar et al. Reference Kumar, Jha and Reichard2014), glyphosate was applied at 1.3 kg ae ha− 1 for B. scoparia, whereas a 0.8 kg ae ha− 1 rate was used for A. retroflexus and C. album. Glufosinate at 0.6 kg ai ha− 1 and dicamba at 0.6 kg ae ha− 1 were applied to all dicot weed species. Monocot weed species were excluded from dicamba screening. Glyphosate applications were made at 0.9, 0.5, and 0.7 kg ae ha− 1 for A. fatua, S. viridis, and E. crus-galli, respectively. Glufosinate was applied at 0.6 kg ai ha− 1 for all monocot species. Ammonium sulfate (20 g L− 1) was added as an adjuvant to glyphosate and glufosinate, and a non-ionic surfactant ( Induce®, Helena Agri-Enterprises, Collierville, TN, USA) (0.25 % v/v) + ammonium sulfate (20 g L− 1) was added to dicamba. Plants were not watered for 12 h following herbicide applications to meet the required rainfast period.

Given the humidity-dependent nature of glufosinate (Coetzer et al. Reference Coetzer, Al-Khatib and Loughin2001), greenhouse relative humidity was elevated to 60% to 80% using an automated misting system (Homenote, Guangzhou, China) before spraying. Plants treated with glufosinate were maintained under elevated humidity conditions throughout the entire experimental period. Specifically, following a 12-h rainfast period, the greenhouse misting system was set to activate at 10-min intervals to maintain >60% humidity throughout the study.

The number of surviving plants (i.e., with green tissue) per population was recorded and converted into percentages to represent survival rates at 28 d after glyphosate and glufosinate applications and 35 d after dicamba application. The populations were subsequently classified into three different categories based on their survival percentages: (1) susceptible (0%), (2) developing resistance (1% to 20%), and (3) resistant (>20%) (scale modified from Owen et al. [Reference Owen, Walsh, Llewellyn and Powles2007]). All herbicide screenings were repeated three times. The screening protocol was collaboratively designed by our team following Simões Araujo et al. (Reference Simões Araujo AL Westra, Shergill and Gaines2024).

Seedling Emergence Dynamics

To address our second and third questions, a greenhouse experiment was conducted at SARC from March to May 2023 in a randomized complete block design with four replications, each consisting of 13, 11, and 4 field and margin populations of B. scoparia, A. retroflexus, and C. album, respectively. The populations were selected based on the presence of field and margin pairs across the surveyed area. The greenhouse was maintained at 22/17 ± 2 C day/night temperatures and a 16/8-h photoperiod. These conditions closely mimic the environmental characteristics of SE Montana and NW Wyoming during late May and early June, which is the usual time frame for the first herbicide application.

Twenty-five seeds of each population were manually counted and stored in paper envelopes. Thermoformed trays (53 by 28 cm, 1020 Heavy duty, CN-FLHD-X1, Greenhouse Megastore) with eight subunits were filled with the same potting mix used in the herbicide screening. Each subunit represented one replication, and each tray contained eight different populations. Twenty-five seeds per population were uniformly placed on the surface of a subunit filled with the potting mix and slightly incorporated. Seeds were not buried into the potting mix due to the surface-emerging nature of all tested species.

Seedling emergence counts were recorded daily for 40 d, and emerged seedlings were removed using forceps. Seedlings were classified as “emerged” when their plumules were visible. Daily emergence counts were aggregated to derive cumulative emergence counts, from which the cumulative emergence percentage (CE%) was calculated (Equation 1).

([1]) $${\rm{CE\% }} = \left( {{{\mathop \sum \nolimits_{i = 1}^t {E_i}}}\over{N}} \right) \times 100$$

where CE% is the cumulative emergence percentage, $\mathop \sum \nolimits_{i=1}^t {E_i}$ is the sum of the emerged seedling(s) from day 1 to day t, and N represents the total number of seeds per experimental unit (i.e., 25) at the start of the experiment. The second run was repeated 20 d after the completion of the first run. Each run was concluded upon the emergence of all seedlings (i.e., 100% emergence).

Statistical Analysis

The data were analyzed in R Studio (v. 4.2.1; R Development Core Team) (RStudio Team, 2020). For herbicide screening, survival (%) data were plotted against the populations of three major weed species. A three-parameter log-logistic regression (Equation 2) was fit to model the cumulative emergence using the drm function from the drc package (Knezevic et al. Reference Knezevic, Streibig and Ritz2007). No violations, including monotonicity and homoscedasticity, were observed in diagnostic plots; therefore, nontransformed data were used for analysis. Data were pooled across two runs, as no significant difference was observed between them. Species differed in their emergence response; therefore, the model was computed separately for each species to capture the unique characteristics of their emergence patterns. In these models, the response, predictor, and categorical variables were CE%, days after sowing (DAS), and population, respectively.

([2]) $${Y} ={ {d}\over{{1 + exp\left[ {b\left( {{\rm{log}}x - log{{\rm{E}}_{50}}} \right)} \right]}}}$$

where Y, x, b, and E50 represent CE%, DAS, the slope of the regression curve (rate of emergence), and x value (DAS) required to reach 50% emergence, respectively. A smaller b value indicates a slow emergence rate. The upper limit d was fixed at 100, because the emergence of all populations was 100%. Additionally, the DAS required for 10% and 90% emergence (E10 and E90, respectively) was quantified with a 95% confidence interval using the ED function of the drc package. The Akaike information criterion (AIC) was used for model selection. A lack-of-fit test (P > 0.05) was performed using the modelFit function to determine whether the selected model adequately described the emergence response. The parameters estimated by the three-parameter log-logistic model were compared based on an approximate t-test using the CompParm and EDcomp functions.

To assess our second question, the relationship between phylogenetic distance and emergence patterns of A. retroflexus, B. scoparia, and C. album, a phylogenetic tree was generated using the V.PhyloMaker2, a package that uses three databases (i.e., TPL, LCVP, and WP, The Plant List, Leipzig Catalogue of Vascular Plants, and World Plants) to create large phylogenies for vascular plants (Jin and Qian Reference Jin and Qian2022). In conjunction, the cophenetic.phylo function in the ape package was used to compute pair-wise interspecific phylogenetic distance (hereafter referred to as InterspecificPD) based on the sum of branch lengths of the shortest path. E10, E50, and E90 data of the three tested weed species were subjected to a one-way ANOVA using the aov function. Mean emergence parameters were separated across the three weed species based on Fisher’s Protected LSD test (α = 0.05). Results of one-way ANOVA and phylogenetic analysis were plotted adjacent to each other using the phytools package.

Results and Discussion

Weed Species Richness and Infestation Pattern

A total of 72 sugar beet fields were visited (Figure 1B), of which 25% were weed-free, 31% were infested by all three major weed species (B. scoparia, A. retroflexus, and C. album), while 25% and 7% had infestations of two and one of three major species, respectively (Figure 1B). Among the surveyed fields, 60%, 56%, and 38% were infested by A. retroflexus, B. scoparia, and C. album, respectively. In four fields (3%), the three other weed species, S. viridis, E. crus-galli, or A. fatua, were observed (Figure 1B).

For B. scoparia, 57.5% of the field populations were isolated, 17.5% were clustered, and 25% were widespread (Figure 1C). Amaranthus retroflexus field populations were present in isolated (37%) and clustered (30%) conditions, while 33% of populations were present in widespread conditions (Figure 1D). For C. album, 63% of the field populations occurred in isolation, 26% in clusters, and 11% in widespread conditions (Figure 1E). These categories provide useful insights into the spatial distribution of weed species, which is crucial for designing effective management strategies. The observed differences in infestation levels between species hold broader ecological and management implications, discussed in the “Management Implications of Triple-stacked Sugar Beet Systems” section. The presence of these weed species before sugar beet harvesting could be attributed to two different evolutionary adaptations: herbicide resistance and/or a temporal shift in emergence dynamics (Essman et al. Reference Essman, Loux, Lindsey, Ackley and Regnier2021), as well as application conditions such as drought stress and/or herbicide application error.

Glyphosate, Glufosinate, and Dicamba Resistance

Bassia scoparia

Out of the 16 populations found in field and margin pairs, 25% showed two-way resistance (glyphosate + dicamba), and 50% of pairs had one-way resistance to glyphosate (Figure 3). Among 24 populations found only in fields, 46% and 42% of them displayed two-way resistance (glyphosate + dicamba) and one-way resistance to glyphosate, respectively (Figure 3). Two-way resistance (glyphosate + dicamba) and one-way glyphosate resistance were observed in 17% and 33% of populations found only in margins, respectively.

Figure 3.

Percentage survival of Bassia scoparia populations from (A) fields and (B) margins collected during August 2021 when sprayed with dicamba (0.6 kg ae ha− 1), glufosinate (0.6 kg ae ha− 1), and glyphosate (1.3 kg ae ha− 1). The numerical values preceded by the letter K represent the surveyed field number. The horizontal truncated black line differentiates populations based on developing resistance (1–20%) and resistance (20%). Isolated, cluster, and widespread indicate the infestation level during the August 2021 survey, while “S” represents the susceptible populations from North Dakota used as a reference line.

Population K13 exhibited >20% survival after being sprayed with glyphosate and glufosinate (Figure 3A). To our knowledge, there is no documented evidence of glufosinate-resistant B. scoparia. Therefore, pending inheritance studies, dose-response assays, and molecular validation, this could be the first glufosinate-resistant B. scoparia case. Additionally, field populations K11, K44, K17, K20, and K23 demonstrated a low level of survival (3% to 9%) to glufosinate, suggesting that a few individuals in these populations may have resistance to glufosinate (Figure 3A), with further investigation of heritability and dose-response required.

The prevalence of glyphosate and dicamba resistance in margin populations, where herbicides are not usually applied, suggests pollen- and seed-mediated gene flow (Beckie et al. Reference Beckie, Blackshaw, Hall and Johnson2016; Jhala et al. Reference Jhala, Norsworthy, Ganie, Sosnoskie, Beckie, Mallory-Smith, Liu, Wei, Wang and Stoltenberg2021; Sarangi et al. Reference Sarangi, Tyre, Patterson, Gaines, Irmak, Knezevic, Lindquist and Jhala2017; Stallings et al. Reference Stallings, Thill, Mallory-Smith and Shafii1995). In B. scoparia, pollen-mediated gene flow can occur up to 100 m due to its highly cross-pollinated nature and protogynous flowers (Beckie et al. Reference Beckie, Blackshaw, Hall and Johnson2016). Also, seed-mediated gene flow can reach up to 1,000 m in B. scoparia, attributed to its tumbling characteristic (Beckie et al. Reference Beckie, Blackshaw, Hall and Johnson2016). In addition, glyphosate-resistant populations K02 and K55 and two-way resistant (glyphosate + dicamba) population K30 were found only in the margins (Figure 3B). Due to the existence of pollen- and seed-mediated gene flow of B. scoparia, herbicide-resistant traits present in margin plants could infest sugar beet fields over time. These results highlight the importance of managing B. scoparia in field margins to minimize the spread of resistant biotypes.

In our study, while glyphosate resistance was observed in 93% of B. scoparia populations, 40% of populations exhibited resistance to dicamba (Figure 3A). These data indicate a rapid evolutionary ability, as glyphosate and dicamba resistance was reported in ∼30% and ∼8% of B. scoparia populations, respectively, in a survey conducted across Colorado from 2012 to 2014 (Westra et al. Reference Westra, Nissen, Getts, Westra and Gaines2019). To date, dicamba resistance has been reported in the United States and Canada in six different dicot weed species, including B. scoparia (Heap Reference Heap2025). Although synthetic auxins such as dicamba have been utilized for >70 yr, resistance to this herbicide class is not as widely documented as other modes of action (e.g., acetolactate synthase, photosystem II, and 5-enolpyruvylshikimate-3-phosphate synthase inhibitors). Relative to glyphosate, the limited distribution of dicamba resistance could be attributed to the associated fitness penalty. For example, in Montana, reduced germination and 39% lower fecundity were observed in the dicamba-resistant B. scoparia compared with the dicamba-susceptible population, suggesting a potential fitness penalty, which may have restricted the spread of dicamba resistance in SE Montana and NW Wyoming (Kumar and Jha Reference Kumar and Jha2016). However, B. scoparia does not necessarily express such fitness penalties in field situations (Menalled and Smith Reference Menalled and Smith2007), suggesting that other demographic mechanisms could also be conditioning the dynamics of dicamba resistance in the region.

Amaranthus retroflexus

Despite the occurrence of A. retroflexus, no populations were identified as resistant to glyphosate, glufosinate, and dicamba (Figure 4A). However, 27% of the 44 populations showed developing resistance (1% to 20% survival) to glyphosate (Figure 4A). Out of the total populations, 7% showed one-way (dicamba) and two-way (glyphosate + dicamba) developing resistance (Figure 4A). We did not detect herbicide resistance in margin populations (n = 16) (data not shown).

Figure 4.

Percentage survival of (A) Amaranthus retroflexus and (B) Chenopodium album populations collected from sugar beet fields during the August 2021 survey when sprayed with dicamba (0.6 kg ae ha− 1), glufosinate (0.6 kg ae ha− 1), and glyphosate (0.8 kg ae ha− 1). The numerical values preceded by the letters P or L represent the surveyed field number. The horizontal truncated black line differentiates populations based on developing resistance (1–20%) and resistance (20%). Isolated, cluster, and widespread indicate the infestation level during the August 2021 survey, while “S” represents the susceptible populations from Montana used as a reference line.

Chenopodium album

For C. album, 78% of the 27 sampled populations showed reduced susceptibility to glyphosate (Figure 4B). However, glyphosate resistance in C. album has not been formally reported, but many populations across the United States show inconsistent responses to glyphosate (Kniss et al. Reference Kniss, Miller, Westra and Wilson2007; Owen Reference Owen2008; Westhoven et al. Reference Westhoven, Stachler, Loux and Johnson2008). No population survived glufosinate application. Population L14 showed developing resistance to dicamba, with 19% survival (Figure 4B). All margin populations (n = 4) were susceptible to glyphosate, glufosinate, and dicamba, except for L03, which displayed dicamba resistance (>35%) (data not shown). Chenopodium album predominantly undergoes autogamy (self-pollination), with a minimal propensity for allogamous (cross-pollination) events (Gasquez Reference Gasquez and Jacquard1985; Holm et al. Reference Holm, Plucknett, Pancho and Herberger1977). As a result, the pollen-mediated gene flow is restricted to only 15 m, and even within this range, the occurrence rate is 0.2% (Yerka et al. Reference Yerka, de Leon and Stoltenberg2012). Therefore, in contrast to B. scoparia, all margin populations of C. album were glyphosate susceptible, despite many field populations surviving glyphosate application.

No herbicide resistance was recorded in A. fatua (n = 1), E. crus-galli (n = 2), and S. viridis (n = 3) populations (data not shown). For B. scoparia, which undergoes cross-pollination, a significant portion of populations collected from margins, as well as those collected in the fields, exhibited herbicide resistance. Conversely, for C. album, a self-pollinated species, reduced susceptibility to glyphosate was widely observed in field populations but notably absent in margin populations. In A. retroflexus, another self-pollinated species, herbicide resistance was not observed in margin populations, and most of the field populations were also found to be susceptible. Addressing our first research question and in accordance with our first hypothesis, our results suggest that the evolution and spread of herbicide resistance in self-pollinated and cross-pollinated species follow distinct patterns due to the differential gene flow rate.

Seedling Emergence Dynamics

The CE% response of B. scoparia, A. retroflexus, and C. album was adequately described by the three-parameter log-logistic model (P > 0.05) (Table 1). No consistent emergence response was observed among populations collected from fields and margins for all tested species. All B. scoparia and C. album populations reached 10% emergence (E10) within 4 to 6 d (Table 1). In contrast, A. retroflexus populations required 4 to 22 d to reach 10% emergence (Table 1). Similarly, E50 values for B. scoparia and C. album populations ranged from 2 to 11 d, while A. retroflexus populations exhibited a wider range, requiring 8 to 32 d (Table 1). Except for K23-field, K32-field, and K47-margin B. scoparia populations, all populations reached E90 within 20 d. Similarly, C. album populations required <20 d to achieve E90. In contrast, all A. retroflexus populations, except P56-field, took >25 d to reach E90. These results suggest that a large proportion of A. retroflexus seedlings tend to emerge later compared with the other two weed species. The delayed and/or extended emergence response of A. retroflexus populations was also reflected by the smaller b values ranging from −2.1 to −17.1. Similar emergence patterns were also documented in giant ragweed (Ambrosia trifida L.) populations growing under the selective pressure of repeated cultivation (Davis et al. Reference Davis, Clay, Cardina, Dille, Forcella, Lindquist and Sprague2013; Hovick et al. Reference Hovick, McArdle, Harrison and Regnier2018; Schutte et al. Reference Schutte, Regnier, Harrison, Schmoll, Spokas and Forcella2008).

Table 1.

Regression parameters estimated by a three-parameter log-logistic model { $Y = d/1 + {\rm{exp}}\left[ {b\left( {{\rm{log}}x - {\rm{log}}{{\rm{E}}_{50}}} \right)} \right]$ } for cumulative emergence percentage of Bassia scoparia, Amaranthus retroflexus, and Chenopodium album populations collected in southeast Montana and northwest Wyoming, USA.

a Letters represent the common names of the weed species: K, kochia, Bassia scoparia; P, redroot pigweed, Amaranthus retroflexus; and L, common lambsquarters, Chenopodium album. The numerical values preceded by letters represent the surveyed field number; for instance, K14 was collected from field 14 and the margins of field 14.

b b, the slope of the curve indicating the emergence rate of populations over time; E10, E50, and E90 represent days required to reach 10%, 50%, and 90% emergence, respectively. Values in parentheses are standard errors of the mean.

Based on the phylogenetic tree (Figure 5), the InterspecificPD values between B. scoparia and C. album and B. scoparia/C. album and A. retroflexus are 80.5 and 87.3, respectively. These data suggest that B. scoparia and C. album are more closely related compared with A. retroflexus. In response to our second research question and in agreement with our second hypothesis, we detected a higher resemblance of emergence patterns between B. scoparia and C. album compared with A. retroflexus (Figure 5; Table 1), showing evidence of phylogenetic niche conservatism (i.e., a positive relationship between phylogenetic distance and functional dissimilarity). Despite the positive relationship between the phylogenetic distance and dissimilarity in emergence patterns across three tested species, the phylogenetic niche conservatism hypothesis is not ubiquitous in trait and lineage and may not be universally justified (Crisp and Cook Reference Crisp and Cook2012; E-Vojtkó et al. Reference E-Vojtkó, de Bello, Lososová and Götzenberger2023). Therefore, a comprehensive analysis exploring the relationship between various weed emergence (dis)similarities and phylogenetic relatedness would provide in-depth insights into weed management, plant systematics, and ecology.

Figure 5.

Phylogenetic relatedness and (dis)similarity of emergence pattern across Bassia scoparia, Chenopodium album, and Amaranthus retroflexus. Different colored boxes represent E10, E50, and E90, which are days required to reach 10%, 50%, and 90% emergence, respectively, estimated by a three-parameter log-logistic model at 22/17 ± 2 C day/night temperatures and a 16/8-h photoperiod. Similar letters denoting nonsignificant differences based on Fisher’s Protected LSD test (α = 0.05) are for E10, E50, and E90 across species.

Unlike B. scoparia and C. album, herbicide resistance was not as prevalent in A. retroflexus (Figure 4A). However, there was a late-season occurrence of 43 populations, potentially reflecting the delayed and extended emergence of the A. retroflexus populations. Additionally, the temperature increases in Montana and Wyoming in late June and early July favor the rapid emergence of A. retroflexus, given its ability to germinate at a higher rate at 35/30 C (Guo and Al-Khatib Reference Guo and Al-Khatib2003). These findings address our third research question and support the third hypothesis, suggesting that a dual evolutionary adaptation—herbicide resistance and delayed/extended emergence—can enable weed species to escape early-season weed management in sugar beet cropping systems.

Most of the B. scoparia populations reached E90 within 20 d, except K23-field, K32-field, and K47-margin, which required 31, 24, and 29 d, respectively (Table 1). However, they reached E10 within 4 d, indicating an extended emergence period. The smaller b values associated with the K23-field (−3.9), K32-field (−3.6), and K47-margin (−3.4) further support the extended emergence of these populations. Given the prevalent herbicide resistance observed (Figure 3) and the extended emergence of these B. scoparia populations, our results support the possibility of dual evolutionary adaptation. In C. album, no population exhibited a temporal shift in emergence (Table 1). Nevertheless, 78% of C. album populations showed reduced susceptibility to glyphosate (Figure 4B), explaining the late-season detection of 27 populations.

The delayed and extended emergence of A. retroflexus and the prolonged emergence period of some B. scoparia populations observed in this study could be a form of phenological adaptation (Délye et al. Reference Délye, Menchari, Michel, Cadet and Le Corre2013; Kumar et al. Reference Kumar, Jha, Dille and Stahlman2018; Mortimer Reference Mortimer1997; Recasens et al. Reference Recasens, Calvet, Cirujeda and Conesa2005) that allows these weed species to evade the burndown herbicide applications, preplanting tillage operations, and in-crop herbicide applications. Therefore, attention should also be given to late-season weed management strategies to manage and prevent seedbank replenishment from the late-emerging cohorts (Kumar and Jha Reference Kumar and Jha2015; Wilson and Sbatella Reference Wilson and Sbatella2011). Considering the short stature of sugar beet, weed electrocution could be a potential nonchemical method for late-emerging and herbicide-resistant weeds (Schreier et al. Reference Schreier, Bish and Bradley2022; Slaven et al. Reference Slaven, Koch and Borger2023). For example, in sugar beet, Peters et al. (Reference Peters, Borgen and Lystad2020) reported 80% and 76% control of escaped waterhemp [Amaranthus tuberculatus (Moq.) Sauer] and B. scoparia using weed electrocution, respectively.

From an eco-evolutionary perspective (Neve et al. Reference Neve, Vila-Aiub and Roux2009), the extended emergence patterns of some B. scoparia populations could lead to sympatric speciation over time, a process by which a new species forms when barriers to gene flow, such as reproductive isolation, develop between groups of populations. Later-emerged B. scoparia seedlings may occupy niches at different times, indicating temporal niche divergence (Vaissi and Rezaei Reference Vaissi and Rezaei2022), which could lead to reproductive isolation (Rundle and Nosil Reference Rundle and Nosil2005). From a weed management perspective, the extended emergence pattern could potentially be exploited by adjusting the crop planting dates to promote size-asymmetric competition, that is, the unequal distribution of resources among consumer species (Weiner Reference Weiner1990) that usually occurs due to initial size advantage and overtopping (Freckleton and Watkinson Reference Freckleton and Watkinson2001). Early planting may enhance crop competitiveness, as crops gain an initial size advantage and significantly suppress the growth of later-emerged weed seedlings (Beckie et al. Reference Beckie, Blackshaw, Leeson, Stahlman, Gaines and Johnson2018).

Management Implications of Triple-stacked Sugar Beet Systems

Sustainable management of herbicide resistance relies on minimizing herbicide usage by integrating other tactics (Hawes et al., Reference Hawes, Haughton, Osborne, Roy, Clark, Perry, Rothery, Bohan, Brooks and Champion2003). In this context, the prevention of weed seedbank replenishment is a fundamental approach for effective herbicide-resistant weed management (Schwartz-Lazaro and Copes Reference Schwartz-Lazaro and Copes2019). During the survey, a large fraction of herbicide-resistant B. scoparia (57.5%) and C. album (63%) populations were present in isolation (Figure 1C and 1E). Given the greater fecundity of B. scoparia and C. album, these isolated populations could be precursors to pervasive infestation if not managed at an early stage. It would be of utmost importance for sugar beet growers to manually uproot these populations or conduct precision applications of alternative herbicides to prevent herbicide-resistant seedbank replenishment.

The clusters of B. scoparia (17.5%) and C. album (26%) (Figure 1C and 1E) could be problematic hotspots due to the accumulation of herbicide-resistant biotypes, suggesting a localized gene flow. Late-season herbicide-based rescue treatments, mechanical removal, and electric weeding could be effective management strategies to prevent the spread of resistance alleles to adjacent fields. Within the sugar beet fields, several B. scoparia populations, namely K07, K17, K23 K47, K54, K59, K68, and K69, existed in clustered and widespread conditions. Interestingly, these populations demonstrated developing resistance to dicamba with <20% survival, suggesting that only a few plants within these populations can produce dicamba-resistant progenies. Fields with widespread herbicide-resistant B. scoparia (25%) and C. album (11%) populations may exceed economic thresholds sooner compared with those with clustered and isolated populations. These fields need immediate interventions and an integrated weed management approach (e.g., crop rotations, multiple tillage operations, layered herbicide applications, and late-season rescue treatments) to ensure long-term and profitable sugar beet productions. Even though herbicide resistance is not as prevalent in A. retroflexus as in B. scoparia and C. album, fields with widespread infestation of A. retroflexus require season-long management to secure production goals due to this weed’s delayed and extended emergence.

The introduction of the glyphosate-resistant sugar beet cultivar provided short-term efficient weed control. Consequently, there has been a shift in philosophy from managing weeds based on an economic threshold (Wilkerson et al. Reference Wilkerson, Wiles and Bennett2002) to zero-tolerance for weed seedbank replenishment (Brunharo et al. Reference Brunharo, Gast, Kumar, Mallory-Smith, Tidemann and Beckie2022). Almost 100% sugar beet production in SE Montana and NW Wyoming is Roundup Ready®. Glyphosate is the predominant herbicide in the Roundup Ready® sugar beet. Other postemergent herbicides (phemedipham + desmedipham [discontinued in the United States], clopyralid, ethofumesate, and triflusulfuron) are rarely used (Peters et al. Reference Peters, Lystad, Khan and Boetel2024). These changes in weed management principles led to overreliance on glyphosate, which escalated the evolution of glyphosate-resistant B. scoparia populations (Kumar et al. Reference Kumar, Jha, Jugulam, Yadav and Stahlman2019). In accordance with our results, the majority of B. scoparia populations in the Great Plains region possess some level of glyphosate resistance (Godar et al. Reference Godar, Stahlman, Jugulam and Dille2015; Kumar et al. Reference Kumar, Jha, Jugulam, Yadav and Stahlman2019; Wiersma et al. Reference Wiersma, Gaines, Preston, Hamilton, Giacomini, Robin Buell, Leach and Westra2015). No effective postemergent options are available for B. scoparia resistant to glyphosate and triflusulfuron (Lawrence and Kniss Reference Lawrence and Kniss2021). Our study also highlights the widespread occurrence of dicamba resistance in 88% of populations of B. scoparia, including the resistance recorded at the developing stage. In the Northern Great Plains, sugar beet is typically cultivated in a 3-yr rotation cycle with corn. While dicamba is not a widely used herbicide in sugar beet, it has been one of the major herbicides used to manage glyphosate-resistant B. scoparia in corn for >30 yr (Wicks et al. Reference Wicks, Martin and Mahnken1993), resulting in the evolution of two-way (glyphosate + dicamba) resistance.

This study determined that a few B. scoparia populations displayed developing resistance to glufosinate (Figure 3), a herbicide not extensively used in the surveyed area. A low level of glufosinate resistance in B. scoparia populations suggests that glufosinate might still be effective against two-way (glyphosate + dicamba) resistant B. scoparia populations if applied as a standalone herbicide in triple-stacked sugar beet. However, previous studies have shown that glufosinate requires ≥60% relative humidity for optimum activity (Coetzer et al. Reference Coetzer, Al-Khatib and Loughin2001; Ramsey et al. Reference Ramsey, Stephenson and Hall2002). In the Northern Great Plains, where relative humidity often ranges from 25% to 35% during summer, suboptimal weed management following glufosinate application is a recurrent issue. Therefore, the long-term stewardship of glufosinate requires integrated weed management that encompasses, but is not limited to, the adoption of novel application technologies, crop rotations, preplanting tillage, herbicide diversification, weed electrocution, rescue herbicide treatment, and manual uprooting. In conclusion, widespread two-way (glyphosate + dicamba) herbicide resistance, developing glufosinate resistance in B. scoparia, and the humidity-dependent nature of glufosinate raise ecological, evolutionary, and management concerns about the long-term suitability of the triple-stacked sugar beet cultivar in semiarid regions of the Northern Great Plains.

Acknowledgments

The authors would like to thank Akam Brar, Devanshi Desai, Gurman Shergill, and Robert Brunner for their technical assistance.

Funding statement

The authors acknowledge research funding from Western Sugar Cooperative and the USDA-NIFA Hatch Project (MONB00932).

Competing interests

No professional competing interests exist.

Footnotes

Associate Editor: Debalin Sarangi, University of Minnesota

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Figure 0

Figure 1. Infestation pattern of the weed species during an August 2021 survey within the sugar beet cropping systems in southeast Montana and northwest Wyoming: (A) surveyed counties highlighted in orange; (B) number of weed species present (species richness); infestation level and spatial pattern of (C) Bassia scoparia; (D) Amaranthus retroflexus; and (E) Chenopodium album.

Figure 1

Figure 2. Categories of sugar beet fields based on weed infestation visually identified during a survey conducted in southeast Montana and northwest Wyoming counties: (A) weed-free, (B) isolated, (C) clustered, and (D) widespread. Black arrows indicate isolated and clustered infestations of weeds.

Figure 2

Figure 3. Percentage survival of Bassia scoparia populations from (A) fields and (B) margins collected during August 2021 when sprayed with dicamba (0.6 kg ae ha− 1), glufosinate (0.6 kg ae ha− 1), and glyphosate (1.3 kg ae ha− 1). The numerical values preceded by the letter K represent the surveyed field number. The horizontal truncated black line differentiates populations based on developing resistance (1–20%) and resistance (20%). Isolated, cluster, and widespread indicate the infestation level during the August 2021 survey, while “S” represents the susceptible populations from North Dakota used as a reference line.

Figure 3

Figure 4. Percentage survival of (A) Amaranthus retroflexus and (B) Chenopodium album populations collected from sugar beet fields during the August 2021 survey when sprayed with dicamba (0.6 kg ae ha− 1), glufosinate (0.6 kg ae ha− 1), and glyphosate (0.8 kg ae ha− 1). The numerical values preceded by the letters P or L represent the surveyed field number. The horizontal truncated black line differentiates populations based on developing resistance (1–20%) and resistance (20%). Isolated, cluster, and widespread indicate the infestation level during the August 2021 survey, while “S” represents the susceptible populations from Montana used as a reference line.

Figure 4

Table 1. Regression parameters estimated by a three-parameter log-logistic model {$Y = d/1 + {\rm{exp}}\left[ {b\left( {{\rm{log}}x - {\rm{log}}{{\rm{E}}_{50}}} \right)} \right]$} for cumulative emergence percentage of Bassia scoparia, Amaranthus retroflexus, and Chenopodium album populations collected in southeast Montana and northwest Wyoming, USA.

Figure 5

Figure 5. Phylogenetic relatedness and (dis)similarity of emergence pattern across Bassia scoparia, Chenopodium album, and Amaranthus retroflexus. Different colored boxes represent E10, E50, and E90, which are days required to reach 10%, 50%, and 90% emergence, respectively, estimated by a three-parameter log-logistic model at 22/17 ± 2 C day/night temperatures and a 16/8-h photoperiod. Similar letters denoting nonsignificant differences based on Fisher’s Protected LSD test (α = 0.05) are for E10, E50, and E90 across species.