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Emergence pattern of horseweed (Erigeron canadensis L.) accessions across Nebraska

Published online by Cambridge University Press:  22 August 2022

Ahmadreza Mobli
Affiliation:
Postdoctoral Research Associate, Department of Agronomy, University of Wisconsin–Madison, Madison, WI, USA
Maxwel Oliveira
Affiliation:
Research Scientist, Department of Agronomy, University of Wisconsin–Madison, Madison, WI, USA
Liberty Butts
Affiliation:
Former Research Technologist, West Central Research and Extension Center, University of Nebraska–Lincoln, North Platte, NE, USA
Chris Proctor
Affiliation:
Associate Extension Educator, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, Lincoln, NE, USA
Nevin Lawrence
Affiliation:
Associate Professor, Panhandle Research and Extension Center, University of Nebraska–Lincoln, Scottsbluff, NE, USA
Rodrigo Werle*
Affiliation:
Assistant Professor, Department of Agronomy, University of Wisconsin–Madison, Madison, WI, USA
*
Author for correspondence: Rodrigo Werle, Department of Agronomy, University of Wisconsin–Madison, Madison, WI 53705. Email: [email protected]
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Abstract

Horseweed is a North American indigenous plant species commonly found in Nebraska cropping systems. Horseweed management is challenging because of horseweed’s prolific seed production, long-distance seed dispersal via wind, competitiveness, and rapid evolution of herbicide resistance. Understanding the horseweed emergence pattern across Nebraska can contribute to implementing effective and more sustainable tactics to minimize its impact on cropping systems. Field studies were conducted during fall and spring from 2016 to 2018 in Lincoln (corn and soybean), North Platte (wheat stubble and soybean), and Scottsbluff (corn and fallow) to investigate the emergence pattern of horseweed accessions from Lincoln, North Platte, and Scottsbluff, NE. Results show that most horseweed seedling emergence occurred in fall (99%) and only a few seedlings emerged in spring across locations, except in the wheat stubble experiment at North Platte, where higher spring emergence was detected (3% to 22%). In four out of six experiments, the density of total emerged seedlings of each accession was greatest when established in their site of origin. Our results suggest that late fall and/or early spring is likely the best timing for horseweed management across Nebraska.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is a work of the US Government and is not subject to copyright protection within the United States. Published by Cambridge University Press on behalf of the Weed Science Society of America.
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© University of Wisconsin-Madison, 2022

Introduction

Horseweed is a native North American plant species in the Asteraceae family that causes major economic losses to worldwide agricultural systems (Bajwa et al. Reference Bajwa, Sadia, Ali, Jabran, Peerzada and Chauhan2016). Horseweed can directly impact crop growth and development (Bajwa et al. Reference Bajwa, Sadia, Ali, Jabran, Peerzada and Chauhan2016; Chahal and Jhala Reference Chahal and Jhala2019), reduce mechanical harvest efficiency (Leroux et al. Reference Leroux, Benoît and Banville1996), and serve as an alternate host of several pests and diseases (Al-Ghamdi et al. Reference Al-Ghamdi, Stewart and Boivin1993; Bajwa et al. Reference Bajwa, Sadia, Ali, Jabran, Peerzada and Chauhan2016). In North America, horseweed is found in field crops, pastures, and orchards and on roadsides (Miller and Miller Reference Miller and Miller1999). Horseweed is well adapted to conservation agriculture, and in Nebraska, it is the most common weed in no-till soybean production (Chahal and Jhala Reference Chahal and Jhala2019). In conservation agriculture systems, herbicides constitute the main weed management option (Bajwa et al. Reference Bajwa, Sadia, Ali, Jabran, Peerzada and Chauhan2016; Marble Reference Marble2015; Nandula et al. Reference Nandula, Eubank, Poston, Koger and Reddy2006). The reliance on herbicides as the primary tool for horseweed management has resulted in the evolution of several herbicide-resistant horseweed biotypes, including resistance to acetolactate synthase (HRAC Group 2), enolpyruvyl shikimate phosphate synthase (HRAC Group 9), photosystem I (electron diversion, HRAC Group 22), and photosystem II (serine 264 binders, HRAC Group 5) inhibitors (Heap Reference Heap2022). There are more than 30 unique cases of horseweed biotypes with either single or multiple herbicide resistance reported in the United States (Heap Reference Heap2022).

Uncontrolled horseweed has been reported to reduce soybean and corn yields up to 98% and 69%, respectively (Bruce and Kells Reference Bruce and Kells1990; Ford et al. Reference Ford, Soltani, Robinson, Nurse, McFadden and Sikkema2014). Crop yield losses are influenced by weed emergence time, density, and interference duration (Estorninos et al. Reference Estorninos, Gealy, Gbur, Talbert and McClelland2005; Hussain et al. Reference Hussain, Khaliq, Matloob, Fahad and Tanveer2015; Lindström and Kokko Reference Lindström and Kokko2002). Time of weed emergence plays an important role in weed growth and fecundity (Davis et al. Reference Davis, Kruger, Young and Johnson2010; Mobli et al. Reference Mobli, Manalil, Khan, Jha and Chauhan2020b). Knowledge of weed emergence patterns provides primary information for management decisions and for understanding the interference potential of weed species (Ogg and Dawson Reference Ogg and Dawson1984). Davis et al. (Reference Davis, Kruger, Young and Johnson2010) suggests that the poor efficacy of herbicide management to control horseweed could be due to lack of emergence pattern understanding leading to incorrect herbicide application timing.

Predicting the emergence time of horseweed is challenging due to lack of seed dormancy and the ability of this species to germinate under a broad range of environmental conditions (Main et al. Reference Main, Steckel, Hayes and Mueller2006; Shrestha et al. Reference Shrestha, Hembree and Wright2008). The environmental conditions and historical site-specific weed management strategies can affect horseweed emergence patterns, for example, repeated fall burndown herbicide applications likely selected for spring-emerging horseweed biotypes in Indiana and Illinois (Davis et al. Reference Davis, Kruger, Young and Johnson2010). Schramski et al. (Reference Schramski, Sprague and Patterson2021) reported that shifts from fall to spring-emerging biotypes expedited glyphosate resistance evolution. Moreover, horseweed is self-pollinated and a prolific seed producer, producing up to 1 million seeds per plant, with effective wind seed dispersal infesting areas up to 550 km away from the source (Bhowmik and Bekech Reference Bhowmik and Bekech1993; Shields et al. Reference Shields, Dauer, VanGessel and Neumann2006; Tozzi and Van Acker Reference Tozzi and Van Acker2014). Therefore horseweed seeds can be easily transferred to neighboring cropping systems, and newly introduced horseweed biotopes with genetic diversity and differential response to management strategies make predicting its emergence pattern and control more difficult. Horseweed exhibits different fall- and spring-emerging phenotypes. The fall-emerging seedlings overwinter as rosettes, and a flowering stem starts to elongate in the spring. In contrast, spring-emerging cohorts grow in the upright form, skipping the overwintering rosette stage (Main et al. Reference Main, Steckel, Hayes and Mueller2006; Schramski et al. Reference Schramski, Sprague and Patterson2021). The differential horseweed growth due to its emergence pattern could increase management complexity, thus warranting studies evaluating horseweed emergence across a range of environmental conditions throughout Nebraska.

A comprehensive investigation of horseweed emergence patterns across Nebraska has not been conducted and can support implementation of more effective and sustainable practices for managing this troublesome weed species. We hypothesized that Nebraska horseweed emerges primarily in the fall. The objective of this study was to evaluate the emergence pattern of three horseweed accessions from Nebraska across multiple locations and cropping systems throughout the state.

Materials and Methods

Plant Material

Horseweed accessions were collected from Lincoln (Lin), North Platte (Npl), and Scottsbluff (Scb), NE, in late August 2016 and again in late August 2017 (Figure 1). Mature horseweed seeds were harvested from 20 arbitrarily selected plants from soybean fields in 2016 and soybean (Npl, Lin) and corn (Scb) fields in 2017. Each accession was collected from a single field. Horseweed seeds were cleaned and briefly stored at 25 C until the onset of experiments in 2016 and 2017. Fresh seeds from all accessions were collected and used for each experimental year.

Figure 1. Locations of horseweed seed collection and research sites across Nebraska.

Field Experiments

The experiments were conducted across Nebraska over two horseweed emergence years (2016 to 2017 and 2017 to 2018) at Lincoln and Scottsbluff and over one horseweed emergence year (2016 to 2017) at North Platte (Figure 1; Table 1). At each location, two experiments were established, representing regional cropping systems. In Lincoln, experiments were established in rainfed corn and rainfed soybean fields; rainfed wheat stubble and irrigated soybean in North Platte; and irrigated corn and rainfed fallow in Scottsbluff (Table 1). Experiments were arranged in a randomized complete block design with 3 horseweed accessions and 6 replications (totaling 18 experimental units). Polyvinyl chloride (PVC) rings with a 30-cm diameter and 10-cm height, with a 2.5-cm lip remaining above the soil surface, were used to delineate the experimental units. For experiments conducted within row-crop systems (i.e., corn and soybean; 76-cm row spacing), PVC rings were buried between crop rows (10 cm from the adjacent ring within the crop row) or arranged in a block for wheat stubble and fallow experiments with 10-cm spacing between rings (Figure 2). A 5-ml aliquot of horseweed seeds from a single accession was spread in each PVC ring, and seeds were lightly incorporated onto the soil surface (0 to 5 mm deep) to provide seed-to-soil contact while simulating seed-rain from naturally occurring horseweed plants. A 5-ml aliquot of horseweed seeds of Lin, Npl, and Scb contained an average of 6,600 (±550) seeds. In Lincoln, an extra treatment was included to monitor the natural horseweed population (“Natural” accession; total of 24 experimental units in each experiment). The study locations at North Platte and Scottsbluff were not naturally infested with horseweed.

Table 1. Field information and soil conditions during horseweed emergence experiments at Lincoln, North Platte, and Scottsbluff, NE, in 2016 to 2018. a

a Abbreviations: Lin, Lincoln, NE; Npl, North Platte, NE; Scb, Scottsbluff, NE.

Figure 2. General scheme of experiment in different seed accessions. Experimental unit established in soybean (A). Experimental unit established in wheat stubble (B). Experiment established in wheat stubble (C). Photographs taken from the experiment established in wheat stubble and soybean, North Platte, NE, in fall 2016.

Emerged seedlings were counted weekly and gently removed by hand from the experimental units with minimum soil disturbance. Emergence counts were conducted from time of fall establishment until late spring, when emergence ceased. The total density of emerged seedlings during the fall and spring (seedlings per experimental unit) was recorded. Emergence data from each observation were converted to cumulative emergence (%) for each accession as follows:

(1) ${\rm{Cumulative \;emergence \;(\% )}} = {{{\rm{Number\;of\;emerged\;seedlings\;}} \times {\rm{\;}}100} \over {{\rm{Total\;seedling\;emergence\;}}}}$

Daily mean air temperature and precipitation for each location were obtained from the nearest High Plains Regional Climate Center automated station (https://hprcc.unl.edu/; Figure 3). Temperature data were converted to growing degree days (GDDs) accumulation from horseweed planting (i = 1) to each data collection time (n = days after i); 5 C was considered as the base temperature for horseweed emergence (Nandula et al. Reference Nandula, Eubank, Poston, Koger and Reddy2006; Ottavini et al. Reference Ottavini, Pannacci, Onofri, Tei and Kryger Jensen2019):

(2) ${\rm{GD}}{{\rm{D}}_5} = {\sum\nolimits_{i = 1}^n {\left\{ {\left[ {{{\left( {{\rm{Maximum\;daily\;temperature\;}} + {\rm{\;Minimum\;daily\;temperature}}} \right)} \over 2}} \right] - 5} \right\}}.}$

Figure 3. Daily mean air temperature, mean soil temperature, and precipitation of Lincoln, NE (A), North Platte, NE (B), and Scottsbluff, NE (C) research sites during the study in 2016 to 2018. Data were adopted from the High Plains Regional Climate Center website, https://hprcc.unl.edu/.

Statistical Analyses

The statistical analyses were performed separately for each cropping system within each location. The data from the two experimental years were pooled, and the year effect was treated as random throughout the statistical analyses. The statistical analyses were performed using R statistical software version 4.1.1 (R Development Core Team 2022). Horseweed cumulative emergence was described using the asymmetrical three-parameter Weibull model (W1.3) of the drc package (Ritz et al. Reference Ritz, Baty, Streibig and Gerhard2015):

(3) $$Y = d\exp \{ - \exp [b(\log (x) - e)]\} $$

where Y is the horseweed cumulative emergence, d is the upper limit (set to 100), e is the inflection point, b is slope, and x is the GDDs.

The required GDDs for 10%, 50%, and 90% horseweed cumulative emergence were estimated using the ED function of the drc package. The 10%, 50%, and 90% horseweed cumulative emergences were compared among horseweed accessions using the EDcomp function of the drc package. The EDcomp function compares the 10%, 50%, and 90% cumulative emergences using t-statistics with a P = 0.05. The root mean square error (RMSE) was calculated as an indicator of goodness of fit for each model according to Roman et al. (Reference Roman, Murphy and Swanton2000):

(4) ${\rm{RMSE}} = {\left[ {1/n\;\mathop \sum \limits_{i = 1}^n {{\left( {{\rm{P}}i - {\rm{O}}i} \right)}^2}} \right]^{1/2}}$

where n is the total number of comparisons and Pi and Oi is the predicted and observed value, respectively. The smaller the RMSE is, the closer are the observed values to the predicted values.

The total horseweed seedling emergence data for each cropping system at each location were analyzed with generalized linear mixed models using the template model builder with the glmmTMB function from the glmmTMB package (Brooks et al. Reference Brooks, Kristensen, Van Benthem, Magnusson, Berg, Nielsen, Skaug, Machler and Bolker2017). In the model, accession and emergence timing (“fall” [September to November] vs. “spring” [March to May]) were the fixed effects and block nested within year as the random effects. Analysis of variance (ANOVA) was performed with the Anova.glmmTMB function from the glmmTMB package at α = 0.05. Marginal means and compact letter display were estimated with *emmeans* and *cld* from package emmeans (Lenth et al. Reference Lenth, Buerkner, Herve, Love, Riebl and Singmann2021) and multcomp (Hothorn et al. Reference Hothorn, Bretz and Westfall2008), respectively, using a least square difference at P = 0.05.

Results

Horseweed Emergence in Lincoln, NE

In the rainfed corn experiment, the required GDDs for 50% cumulative emergence and density of emerged seedlings varied across horseweed accessions (Figure 4; Table 2; P < 0.05). The Lin and Natural accessions required 100 and 161 GDDs for 50% emergence, respectively, which was the least and greatest among the accessions (Table 2). No differences (P = 0.18) were observed between required GDDs for 50% emergence of Npl (108 total emerged seedlings experimental unit−1) and Scb (123) accessions. In addition, more than 99% of total horseweed seedlings across accessions emerged in the fall, whereas only a few seedlings (<1%) emerged in the subsequent spring (Table 3). The greatest fall emergence density was observed for Lin (average of 852), followed by Npl (770), Scb (670), and Natural (280).

Figure 4. Cumulative emergence (%) of horseweed accessions collected in Lincoln, NE (Lin), North Platte, NE (Npl), and Scottsbluff, NE (Scb), at Lincoln (A), North Platte (B), and Scottsbluff (C) research locations. Model parameters are described in Table 2.

Table 2. GDD requirement for 10%, 50%, and 90% cumulative emergence for accessions collected in Lincoln, North Platte, and Scottsbluff, NE, at Lincoln, North Platte, and Scottsbluff research locations.a,b

a In brackets are the 95% confidence interval upper and lower limits.

b Abbreviations: GDD, growing degree day; Lin, Lincoln, NE; Npl, North Platte, NE; RMSE; root mean square error; Scb, Scottsbluff, NE.

c Y = d exp{−exp[b(log(x) − e)]}, where Y is the horseweed cumulative emergence, d is the upper limit (set to 100), e is the inflection point, b is slope, and x is the GDDs. In parentheses is standard error.

d In Lincoln, an extra treatment was included to monitor the natural horseweed population (Natural).

Table 3. Total emergence of horseweed seedlings for accessions collected in Lincoln, North Platte, and Scottsbluff, NE, at Lincoln, North Platte, and Scottsbluff research locations.a,b

a Letters show grouping differences between means for fall and spring emergence cohorts within each experiment at each research site.

b Abbreviations: Lin, Lincoln, NE; Npl, North Platte, NE; Scb, Scottsbluff, NE.

c In Lincoln, an extra treatment was included to monitor the natural horseweed population (Natural).

In the rainfed soybean experiment, no difference (P ≥ 0.23) was observed for 50% (184 to 194 GDDs) cumulative emergence among the horseweed accessions (Figure 4; Table 2). In the fall, the average horseweed density varied from 127 (Natural) to 322 (Npl) seedlings experimental unit−1 (Table 3). More than 99% of horseweed seedlings from all accessions emerged in the fall.

Horseweed Emergence in North Platte, NE

In the rainfed wheat stubble experiment, the Scb (165 total emerged seedlings experimental unit−1) required fewer GDDs for 50% emergence compared to the Lin accession, and there was no difference (P = 0.21) between Lin (245) and Npl (211) (Figure 4; Table 2). The density of emerged seedlings of the Npl (337) in fall was greatest compared to the other accessions (Table 3). More than 78% of horseweed seedlings from all accessions emerged in the fall.

In the irrigated soybean experiment, the Npl accession required more GDDs for 50% emergence compared to the Scb (94 total emerged seedlings experimental unit−1) accession; no difference (P = 0.43) was detected between Lin (158) and Npl (172) for the required GDDs for 50% emergence. Most seedlings emerged in the fall (>99%; Table 2). The greatest fall emergence density was observed for Npl (174), followed by Scb (107) and Lin (46) (Table 3).

Horseweed Emergence in Scottsbluff, NE

In the irrigated corn experiment, the Npl (94 total emerged seedlings experimental unit−1) and Scb (100) accessions required fewer GDDs for 50% than the Lin (114) accession (Figure 4; Table 2). Seedling emergence occurred only in fall (100%; Table 3). In the corn experiment, the seedling emergence density of the Scb (792) was greatest, and the seedling emergence density of the Lin (14) was lowest.

In the rainfed fallow experiment, no difference (P ≥ 0.09) was observed for 50% (68 to 80 GDDs) cumulative emergence among horseweed accessions. No seedling emergence occurred in spring (100% fall emergence; Table 3), and the density of emerged seedlings in the fall was similar across accessions (P > 0.05; 17 to 21 seedlings experimental unit−1).

Discussion

Horseweed has a high ability to adapt to new environments (Bajwa et al. Reference Bajwa, Sadia, Ali, Jabran, Peerzada and Chauhan2016; Nandula et al. Reference Nandula, Eubank, Poston, Koger and Reddy2006). Horseweed is reported as a semi–water stress–tolerant species (Bajwa et al. Reference Bajwa, Sadia, Ali, Jabran, Peerzada and Chauhan2016; Nandula et al. Reference Nandula, Eubank, Poston, Koger and Reddy2006). In laboratory conditions, horseweed maintained its emergence at water potential −0.8 Mpa and NaCl concentration of 200 Mm; however, emergence was reduced under these stressful conditions (Nandula et al. Reference Nandula, Eubank, Poston, Koger and Reddy2006). The Scottsbluff location received periodic rainfall during the growing season (Figure 1); the supplementary irrigation in the corn experiment exhibits the potential emergence fitness of the Scb compared to other accessions in more favorable moisture conditions (Table 2). In the Lincoln location, the Natural accession required greater GDDs for 50% emergence than the other introduced accessions (only at the rainfed corn experiment); however, all introduced accessions responded similarly. It is well understood that genetic diversity and different maternal conditions during seed production among populations of a species may cause differences in seedling emergence (Geng et al. Reference Geng, Van Klinken, Sosa, Li, Chen and Xu2016; Gioria and Pyšek Reference Gioria and Pyšek2017). In the current study, differences among accessions across environmental conditions were observed. However, except for two out of six experiments (fallow experiment at Scottsbluff and soybean experiment at Lincoln), the greatest density of emerged seedlings of each accession was observed in their location of origin. This showcases the effect of local environmental conditions during seed production (aka maternal effect) as the same seed source was used during the study. The unique ecophysiological features of horseweed, such as prolific seed production, long-distance seed dispersal via wind, and competitiveness, make it able to invade and establish in a broad range of environments (Bajwa et al. Reference Bajwa, Sadia, Ali, Jabran, Peerzada and Chauhan2016; Ottavini et al. Reference Ottavini, Pannacci, Onofri, Tei and Kryger Jensen2019; Yan et al. Reference Yan, Feng, Zhao, Feng, Zhu, Qu and Wang2020). Therefore special attention should be paid to implementing tactics that can reduce its introduction and establishment into neighboring areas.

Microsite conditions are critical for horseweed emergence, as seed dormancy is not reported for this species (Regehr and Bazzaz Reference Regehr and Bazzaz1979; Weaver Reference Weaver2001). Crop residue and crop canopy act as physical barriers and can affect the microsite soil hydrothermal conditions and light transmission to topsoil (Grundy and Bond Reference Grundy and Bond2007; Teasdale Reference Teasdale1996). Crop residue on the soil surface may increase water availability to trigger seed germination; however, low crop residue levels (e.g., absence of a physical barrier on the soil surface) may result in higher weed emergence and establishment (Chauhan and Johnson Reference Chauhan and Johnson2011; Mobli and Chauhan Reference Mobli and Chauhan2020a). Daily temperature fluctuation has been reported not to influence the emergence of horseweed, and light exposure is not a mandatory factor for its germination (Nandula et al. Reference Nandula, Eubank, Poston, Koger and Reddy2006; Ottavini et al. Reference Ottavini, Pannacci, Onofri, Tei and Kryger Jensen2019). In the current study, the effect of cropping systems on horseweed emergence suppression was not directly compared; therefore further studies are required to fully understand the effects of cropping systems on horseweed emergence.

In the selected research sites in Nebraska, fresh horseweed seeds could emerge from late summer to late spring (September to June). However, most seedling emergence occurred in the fall (>99%), and only a few seedlings (except for the rainfed wheat stubble experiment at North Platte, where higher spring emergence was detected [3% to 22%]) emerged in the spring. The present study demonstrates that the horseweed accessions from Nebraska have a predominant fall emergence window that may reflect common agronomic practices across the state (widespread adoption of no-till soil conservation practices and fall burndown herbicide applications not as a standard practice). In contrast, in previous studies in Indiana and Illinois, most horseweed emerged in the spring (Davis et al. Reference Davis, Kruger, Young and Johnson2010). Spring emergence has also been reported in Michigan (Schramski et al. Reference Schramski, Sprague and Patterson2021). Bhowmik and Bekech (Reference Bhowmik and Bekech1993) hypothesized that shifted horseweed emergence from fall to spring could be a mechanism to escape from fall management (e.g., fall herbicide burndown, fall tillage). Therefore management strategies should be designed based on the emergence pattern in each location and weed management history. In Nebraska corn–soybean rotations, horseweed management after crop harvest can be beneficial. However, the environmental conditions following crop harvest in the fall are not always favorable for management strategies, and under unfavorable conditions, growers would have to wait until conditions become suitable early in the spring.

The results from this study provide primary input for decision-making models and could contribute to developing effective horseweed management practices across Nebraska cropping systems. Late fall or early spring management with effective burndown herbicide(s) or shallow tillage could be an option for management of fall-emerging cohorts. Alternatively, cover crops are considered as one of the most compatible nonchemical horseweed management strategies in no-till corn–soybean rotations. Fall cover crops can reduce horseweed density and the evolution of herbicide-resistant biotypes (DeSimini et al. Reference DeSimini, Gibson, Armstrong, Zimmer, Maia and Johnson2020; Wallace et al. Reference Wallace, Curran and Mortensen2019; Werle et al. Reference Werle, Burr and Blanco-Canqui2017). Although most seedlings emerged in the fall, management of spring cohorts should not be neglected, as horseweed is a prolific seed producer, and continuous development of fall horseweed management strategies may increase the selection pressure on spring-emerging biotypes, as has been observed in other states.

Acknowledgments

The authors thank all students and staff who assisted with data collection from the field experiments and Breno Nyssen for counting horseweed seeds from each accession. This research received no specific grant from any funding agency or the commercial or not-for-profit sectors. The authors declare no conflicts of interest.

Footnotes

Associate Editor: Prashant Jha, Iowa State University

References

Al-Ghamdi, KM, Stewart, RK, Boivin, G (1993) Note on overwintering of Polynema pratensiphagum (Walley) (hymenoptera: Mymaridae) in southwestern Quebec. Can Entomol 125:407408 CrossRefGoogle Scholar
Bajwa, AA, Sadia, S, Ali, HH, Jabran, K, Peerzada, AM, Chauhan, BS (2016) Biology and management of two important Conyza weeds: a global review. Environ Sci Pollut Res 23:2469424710 CrossRefGoogle Scholar
Bhowmik, PC, Bekech, MM (1993) Horseweed (Conyza canadensis) seed production, emergence, and distribution in no-tillage and conventional-tillage corn (Zea mays). Agronomy 1:6771 Google Scholar
Brooks, ME, Kristensen, K, Van Benthem, KJ, Magnusson, A, Berg, CW, Nielsen, A, Skaug, HJ, Machler, M, Bolker, BM (2017) glmmTMB balances speed and flexibility among packages for zero-inflated generalized linear mixed modeling. R J 9:378400 CrossRefGoogle Scholar
Bruce, JA, Kells, JJ (1990) Horseweed (Conyza canadensis) control in no-tillage soybeans (Glycine max) with preplant and preemergence herbicides. Weed Technol 4:642647 CrossRefGoogle Scholar
Chahal, PS, Jhala, AJ (2019) Integrated management of glyphosate-resistant horseweed (Erigeron canadensis) with tillage and herbicides in soybean. Weed Technol 33:859866 CrossRefGoogle Scholar
Chauhan, BS, Johnson, DE (2011) Ecological studies on Echinochloa crus-galli and the implications for weed management in direct-seeded rice. Crop Protect 30:13851391 CrossRefGoogle Scholar
Davis, VM, Kruger, GR, Young, BG, Johnson, WG (2010) Fall and spring preplant herbicide applications influence spring emergence of glyphosate-resistant horseweed (Conyza canadensis). Weed Technol 24:1119 CrossRefGoogle Scholar
DeSimini, SA, Gibson, KD, Armstrong, SD, Zimmer, M, Maia, LO, Johnson, WG (2020) Effect of cereal rye and canola on winter and summer annual weed emergence in corn. Weed Technol 34:787793 CrossRefGoogle Scholar
Estorninos, LE, Gealy, DR, Gbur, EE, Talbert, RE, McClelland, MR (2005) Rice and red rice interference. II. Rice response to population densities of three red rice (Oryza sativa) ecotypes. Weed Sci 53:683689 CrossRefGoogle Scholar
Ford, L, Soltani, N, Robinson, DE, Nurse, RE, McFadden, A, Sikkema, PH (2014) Canada fleabane (Conyza canadensis) control with preplant applied residual herbicides followed by 2,4-D choline/glyphosate DMA applied postemergence in corn. Can J Plant Sci 94:12311237 CrossRefGoogle Scholar
Geng, Y, Van Klinken, RD, Sosa, A, Li, B, Chen, J, Xu, CY (2016) The relative importance of genetic diversity and phenotypic plasticity in determining invasion success of a clonal weed in the USA and China. Front Plant Sci 7:213 CrossRefGoogle ScholarPubMed
Gioria, M, Pyšek, P (2017) Early bird catches the worm: germination as a critical step in plant invasion. Biol Invasions 19:10551080 CrossRefGoogle Scholar
Grundy, AC, Bond, B (2007) Use of non-living mulches for weed control. Pages 135153 in Upadhyaya MK, Blackshaw RE, eds. Nonchemical Weed Management: Principles, Concepts and Technology. Oxford, UK: Cabi.CrossRefGoogle Scholar
Heap, I (2022) International Survey of Herbicide-Resistant Weeds. http://weedscience.org/. Accessed: May 9, 2022Google Scholar
Hothorn, T, Bretz, F, Westfall, P (2008) Simultaneous inference in general parametric models. Biom J 50:346363 CrossRefGoogle ScholarPubMed
Hussain, S, Khaliq, A, Matloob, A, Fahad, S, Tanveer, A (2015) Interference and economic threshold level of little seed canary grass in wheat under different sowing times. Environ Sci Pollut Res 22:441449 CrossRefGoogle ScholarPubMed
Lenth, RV, Buerkner, P, Herve, M, Love, J, Riebl, H, Singmann, H (2021) emmeans: Estimated Marginal Means, aka Least-Squares Means. R Package v. 4.1.0. https://CRAN.R-project.org/package=emmeans. Accessed: August 24, 2021Google Scholar
Leroux, GD, Benoît, DL, Banville, S (1996) Effect of crop rotations on weed control, Bidens cernua and Erigeron canadensis populations, and carrot yields in organic soils. Crop Protect 15:171178 CrossRefGoogle Scholar
Lindström, J, Kokko, H (2002) Cohort effects and population dynamics. Ecol Lett 5:338344 CrossRefGoogle Scholar
Main, CL, Steckel, LE, Hayes, RM, Mueller, TC (2006) Biotic and abiotic factors influence horseweed emergence. Weed Sci 54:11011105 CrossRefGoogle Scholar
Marble, SC (2015) Herbicide and mulch interactions: a review of the literature and implications for the landscape maintenance industry. Weed Technol 29:341349 CrossRefGoogle Scholar
Miller, JH, Miller, KV (1999) Forest plants of the Southeast and their wildlife uses. Auburn, AL: Southern Weed Science Society. 42 pGoogle Scholar
Mobli, A, Chauhan, BS (2020a) Crop residue retention suppresses seedling emergence and biomass of winter and summer Australian weed species. Weed Biol Manag 20:118128 CrossRefGoogle Scholar
Mobli, A, Manalil, S, Khan, AM, Jha, P, Chauhan, BS (2020b) Effect of emergence time on growth and fecundity of Rapistrum rugosum and Brassica tournefortii in the northern region of Australia. Sci Rep 10:15979 CrossRefGoogle ScholarPubMed
Nandula, VK, Eubank, TW, Poston, DH, Koger, CH, Reddy, KN (2006) Factors affecting germination of horseweed (Conyza canadensis). Weed Sci 54:898902 CrossRefGoogle Scholar
Ogg, AG, Dawson, JH (1984) Time of emergence of eight weed species. Weed Sci 32:327335 CrossRefGoogle Scholar
Ottavini, D, Pannacci, E, Onofri, A, Tei, F, Kryger Jensen, P (2019) Effects of light, temperature, and soil depth on the germination and emergence of Conyza canadensis (L.) Cronq. Agronomy 9:533 CrossRefGoogle Scholar
R Development Core Team (2022) R: A Language and Environment for Statistical Computing. Vienna, Austria: R Foundation for Statistical Computing. https://www.R-project.org/. Accessed: May 9, 2022Google Scholar
Regehr, DL, Bazzaz, FA (1979) The population dynamics of Erigeron canadensis, a successional winter annual. J Ecol 67:923933 CrossRefGoogle Scholar
Ritz, C, Baty, F, Streibig, JC, Gerhard, D (2015) Dose-response analysis using R. PLoS ONE 482(10):e0146021 CrossRefGoogle Scholar
Roman, ES, Murphy, SD, Swanton, CJ (2000) Simulation of Chenopodium album seedling emergence. Weed Sci 48:217224 CrossRefGoogle Scholar
Schramski, JA, Sprague, CL, Patterson, EL (2021) Environmental cues affecting horseweed (Conyza canadensis) growth types and their sensitivity to glyphosate. Weed Sci 69:412421 CrossRefGoogle Scholar
Shields, EJ, Dauer, JT, VanGessel, MJ, Neumann, G (2006) Horseweed (Conyza canadensis) seed collected in the planetary boundary layer. Weed Sci 54:10631067 CrossRefGoogle Scholar
Shrestha, A, Hembree, K, Wright, S (2008) Biology and management of horseweed and hairy fleabane in California. ANR Publ. 8314. Oakland, CA: University of California Agriculture and Natural Resources. 9 pGoogle Scholar
Teasdale, JR (1996) Contribution of cover crops to weed management in sustainable agricultural systems. J Prod Agric 9:475479 CrossRefGoogle Scholar
Tozzi, E, Van Acker, RC (2014) Effects of seedling emergence timing on the population dynamics of horseweed (Conyza canadensis var. canadensis). Weed Sci 62:451456 CrossRefGoogle Scholar
Wallace, J, Curran, W, Mortensen, D (2019) Cover crop effects on horseweed (Erigeron canadensis) density and size inequality at the time of herbicide exposure. Weed Sci 67:327338 CrossRefGoogle Scholar
Weaver, SE (2001) The biology of Canadian weeds. 115. Conyza canadensis . Can J Plant Sci 81:867875 CrossRefGoogle Scholar
Werle, R, Burr, C, Blanco-Canqui, H (2017) Cereal rye cover crop suppresses winter annual weeds. Can J Plant Sci 98:498500 Google Scholar
Yan, H, Feng, L, Zhao, Y, Feng, L, Zhu, C, Qu, Y, Wang, H (2020) Predicting the potential distribution of an invasive species, Erigeron canadensis L., in China with a maximum entropy model. Glob Ecol Conserv 21:e00822 CrossRefGoogle Scholar
Figure 0

Figure 1. Locations of horseweed seed collection and research sites across Nebraska.

Figure 1

Table 1. Field information and soil conditions during horseweed emergence experiments at Lincoln, North Platte, and Scottsbluff, NE, in 2016 to 2018.a

Figure 2

Figure 2. General scheme of experiment in different seed accessions. Experimental unit established in soybean (A). Experimental unit established in wheat stubble (B). Experiment established in wheat stubble (C). Photographs taken from the experiment established in wheat stubble and soybean, North Platte, NE, in fall 2016.

Figure 3

Figure 3. Daily mean air temperature, mean soil temperature, and precipitation of Lincoln, NE (A), North Platte, NE (B), and Scottsbluff, NE (C) research sites during the study in 2016 to 2018. Data were adopted from the High Plains Regional Climate Center website, https://hprcc.unl.edu/.

Figure 4

Figure 4. Cumulative emergence (%) of horseweed accessions collected in Lincoln, NE (Lin), North Platte, NE (Npl), and Scottsbluff, NE (Scb), at Lincoln (A), North Platte (B), and Scottsbluff (C) research locations. Model parameters are described in Table 2.

Figure 5

Table 2. GDD requirement for 10%, 50%, and 90% cumulative emergence for accessions collected in Lincoln, North Platte, and Scottsbluff, NE, at Lincoln, North Platte, and Scottsbluff research locations.a,b

Figure 6

Table 3. Total emergence of horseweed seedlings for accessions collected in Lincoln, North Platte, and Scottsbluff, NE, at Lincoln, North Platte, and Scottsbluff research locations.a,b