Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-10T18:10:46.410Z Has data issue: false hasContentIssue false

Control of Photosystem II– and 4-Hydroxyphenylpyruvate Dioxygenase Inhibitor–Resistant Palmer Amaranth (Amaranthus palmeri) in Conventional Corn

Published online by Cambridge University Press:  19 February 2018

Parminder S. Chahal
Affiliation:
Graduate Research Assistant, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, Lincoln, NE, USA
Suat Irmak
Affiliation:
Professor, Department of Biological Systems Engineering, University of Nebraska, Lincoln, NE, USA
Todd Gaines
Affiliation:
Assistant Professor, Department of Bioagricultural Sciences and Pest Management, Colorado State University, Fort Collins, CO, USA
Keenan Amundsen
Affiliation:
Associate Professor, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, NE, USA
Mithila Jugulam
Affiliation:
Associate Professor, Department of Agronomy, Kansas State University, Manhattan, KS, USA
Prashant Jha
Affiliation:
Associate Professor, Southern Agricultural Research Center, Montana State University, Huntley, MT, USA
Ilias S. Travlos
Affiliation:
Assistant Professor, Department of Crop Science, Agricultural University of Athens, Athens, Greece
Amit J. Jhala*
Affiliation:
Assistant Professor, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, NE, USA
*
*Author for correspondence: Amit J. Jhala, Department of Agronomy and Horticulture, University of Nebraska–Lincoln, Lincoln, NE 68583. (E-mail: Amit.Jhala@unl.edu)
Rights & Permissions [Opens in a new window]

Abstract

Palmer amaranth, a dioecious summer annual weed species, is the most troublesome weed in agronomic crop production systems in the United States. Palmer amaranth resistant to photosystem (PS) II- and 4-hydroxyphenylpyruvate dioxygenase (HPPD) inhibitors is of particular concern in south central Nebraska. The objectives of this study were to determine the effect of PRE followed by POST herbicide programs on PS II- and HPPD-inhibitor-resistant Palmer amaranth control, crop yield, and net economic return in conventional corn. A field study was conducted in 2014, 2015, and 2016 in a grower’s field infested with PS II- and HPPD-inhibitor-resistant Palmer amaranth near Shickley in Fillmore County, Nebraska. A contrast analysis suggested that mesotrione+S-metolachlor+atrazine applied PRE provided 83% Palmer amaranth control at 21 d after application compared to 78 and 72% control with pyroxasulfone+fluthiacet-ethyl+atrazine and saflufenacil+dimethenamid-P, respectively. Most of the PRE followed by POST herbicide programs provided ≥85% Palmer amaranth control. Based on contrast analysis, POST application of dicamba+diflufenzopyr provided 93% Palmer amaranth control compared to 87, 79, and 42% control with dicamba, dicamba+halosulfuron, and acetochlor, respectively, at 28 d after POST. All PRE followed by POST herbicide programs, aside from mesotrione+S-metolachlor+atrazine followed by acetochlor (2,530 to 7,809 kg ha−1), provided 9,550 to 10,500 kg ha−1 corn yield compared with 2,713 to 6,110 kg ha−1 from nontreated control. Similarly, PRE followed by POST herbicide programs, except for mesotrione+S-metolachlor+atrazine followed by acetochlor ($191 and $897 ha−1), provided similar net return of $427 to $707 ha−1 and $1,127 to $1,727 ha−1 in 2014 and 2015-16, respectively. It is concluded that herbicide programs based on multiple sites of action are available for control of PS II- and HPPD-inhibitor-resistant Palmer amaranth in conventional corn.

Type
Weed Management-Major Crops
Copyright
© Weed Science Society of America, 2018 

Palmer amaranth, a native plant of the southwestern United States, is a C4 dioecious species belonging to the family Amaranthaceae (Sauer Reference Sauer1957). Palmer amaranth biotypes resistant to microtubule- (Group 3), acetolactate synthase- (Group 2), photosystem (PS) II- (Group 5), 5-enol-pyruvylshikimate-3-phosphate synthase- (Group 9), hydroxyphenylpyruvate dioxygenase- (HPPD; Group 27), and protoporphyrinogen oxidase- (Group 14) inhibitors have been reported in different states in the United States (Heap Reference Heap2017). Palmer amaranth biotypes resistant to two or more herbicide sites of action have also been confirmed (Heap Reference Heap2017; Jhala et al. Reference Jhala, Sandell, Rana, Kruger and Knezevic2014), thus reducing the number of available herbicide control options.

Nebraska is the third largest producer of corn in the United States, with 3.8 million hectares planted in 2017 (USDA-NASS 2017). A Palmer amaranth biotype resistant to PS II- (atrazine) and HPPD-inhibitors (mesotrione, tembotrione, and topramezone) was reported in a continuous seed corn production field in south-central Nebraska (Jhala et al. Reference Jhala, Sandell, Rana, Kruger and Knezevic2014). PS II- and HPPD-inhibitors are the most commonly used herbicides for weed control in corn because of their PRE and POST activity, broad weed control spectrum, and crop safety, particularly in sweet corn, seed corn, and popcorn (Bollman et al. Reference Bollman, Boerboom, Becker and Fritz2008; Fleming et al. Reference Fleming, Banks and Legg1988; Swanton et al. Reference Swanton, Gulden and Chandler2007). The evolution of PS II- and HPPD-inhibitor–resistant Palmer amaranth in Nebraska is a management challenge for growers because it reduces the number of herbicide options for effective Palmer amaranth control in corn. Additionally, a Palmer amaranth biotype resistant to glyphosate has recently been confirmed in a production field under glyphosate-resistant (GR) corn–soybean rotation in south-central Nebraska (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017).

Several growers avoid PRE herbicide application to reduce production costs and depend only on POST herbicides such as glyphosate for weed control. Schuster and Smeda (Reference Schuster and Smeda2007) reported reduced common waterhemp density (<5 plants m−2) at 25 d after PRE (DAPRE) herbicide applications in corn compared to no weed suppression without PRE. Avoiding PRE herbicides allows early-season crop–weed competition. Corn has a critical period of weed control up to six to seven weeks after emergence or the 3- to 14-leaf stage, and weed competition during this stage could result in a yield penalty (Hall et al. Reference Hall, Swanton and Anderson1992). In addition, avoiding PRE herbicides can cause high weed densities at the POST application timing, resulting in a potential increase in weed selection pressure for resistance against POST herbicides. Growers need alternative herbicide programs for effective management of herbicide-resistant (HR) Palmer amaranth in their production fields. This includes a combination of PRE followed by POST herbicides with multiple sites of action, herbicide rotation, rotation of HR crop traits, and rotation with conventional cultivars (Norsworthy et al. Reference Norsworthy, Ward, Shaw, Llewellyn, Nichols, Webster, Bradley, Frisvold, Powles, Burgos, Witt and Barrett2012; Oliveira et al. Reference Oliveira, Jhala, Gaines, Irmak, Amundsen, Scott and Knezevic2017).

The development of HR crops involves the selection of resistance traits using traditional genetic methods or the integration of transgenic traits using genetic engineering, an expensive and time-consuming process until seed commercialization (Reddy and Nandula Reference Reddy and Nandula2012). Growers purchasing HR crop seeds are required to sign the seed company’s technology/stewardship agreement, which does not allow them to use the harvested seed for planting in the future (Anonymous 2017b; Anonymous 2017d). Therefore, growers need to purchase the HR crop seeds every season. Additionally, growers are required to pay technology fees along with the seed cost for HR crops, which increases production costs (Edwards et al. Reference Edwards, Jordan, Owen, Dixon, Young, Wilson, Weller and Shaw2014; Johnson et al. Reference Johnson, Bradley, Hart, Buesinger and Massey2000; Rice et al. Reference Rice, Mesbah and Miller2001). The south-central area of Nebraska has a significant number of fields under hybrid seed corn production and GR corn–soybean rotation (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017; Jhala et al. Reference Jhala, Sandell, Rana, Kruger and Knezevic2014). Additionally, the area under conventional corn production has been increasing in Nebraska for the last few years to reduce the cost of production due to low commodity prices and the rotation of herbicides with different sites of action, specifically to reduce the overreliance on glyphosate, as six weed species have evolved resistance to glyphosate in Nebraska (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017; Ganie and Jhala Reference Ganie and Jhala2017; Heap Reference Heap2017; Sarangi et al. Reference Sarangi, Sandell, Knezevic, Aulakh, Lindquist, Irmak and Jhala2015).

Information is not available regarding the control of PS II- and HPPD-inhibitor–resistant Palmer amaranth in conventional corn. The objectives of this study were to determine the effect of PRE followed by POST herbicide programs on PS II- and HPPD- inhibitor–resistant Palmer amaranth control, crop yield, and net economic return in conventional corn. We hypothesized that multiple sites of action PRE followed by POST herbicide programs will provide effective control of PS II- and HPPD- inhibitor–resistant Palmer amaranth and prevent yield reductions in conventional corn.

Materials and Methods

A field study was conducted in 2014, 2015, and 2016 in a grower’s field in which the presence of PS II- and HPPD-inhibitor–resistant Palmer amaranth had been confirmed near Shickley in Fillmore County, Nebraska (40.46°N, 97.80°E). The field had been under seed corn production for the previous eight years, with continual use of PS II- and HPPD-inhibiting herbicides. Soil at the experimental site was a Crete silt loam (fine, smectitic, mesic Pachic Udertic Argiustolls) with a pH of 6.5, 26% sand, 57% silt, 17% clay, and 3.5% organic matter. Conventional corn hybrid Stine 9631E was seeded at 87,500 seeds ha−1 in rows spaced 76 cm apart on June 3, 2014; May 30, 2015; and June 1, 2016. Herbicide programs were arranged in a randomized complete block design with four blocks using field slope as the blocking factor. The experimental site was under a center-pivot irrigation system and plots were 3 m wide and 9 m long, consisting of four rows of corn. Monthly mean air temperatures, along with total precipitation during the 2014, 2015, and 2016 growing seasons and the 30-year average for the research site, are provided in Table 1. During 2014 and 2015, 13 to 28 cm of rainfall was received within 2 DAPRE, while 7 cm of rainfall was received at 14 DAPRE at the experimental site in 2016.

Table 1 Monthly mean air temperature and total precipitation during the 2014, 2015, and 2016 growing seasons and 30-year averages at Shickley, Nebraska.Footnote a

a Mean air temperature and total precipitation data were obtained from NWS-COOP (2017).

Herbicide programs included PRE followed by POST herbicides with a total of 16 program combinations, including a nontreated control (Table 2). The herbicide rates and application timings, depending on Palmer amaranth growth stage, were based on herbicide label recommendations in corn in Nebraska. Herbicides were applied with a CO2-pressurized backpack sprayer consisting of a four-nozzle boom fitted with AIXR 110015 flat-fan nozzles (TeeJet Spraying Systems Co., P.O. Box 7900, Wheaton, IL 60189) calibrated to deliver 140 Lha−1 at 276 kPa. PRE herbicides were applied within 3 d after planting corn, and POST herbicides were applied when Palmer amaranth was 12 to 15 cm tall.

Table 2 Herbicide products, rates, and application timing for control of photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.Footnote a

a Abbreviations: AMS, ammonium sulfate (DSM Chemicals North America Inc., Augusta, GA); fb, followed by; NIS, nonionic surfactant (Induce, Helena Chemical Co., Collierville, TN); POST, postemergence; PRE, preemergence.

b All POST herbicide programs except acetochlor were mixed with AMS at 2.5% (wt/v) and NIS at 0.25% (v/v). PRE applications were made within 3 d after planting corn, and POST herbicides were applied when Palmer amaranth was 12 to 15 cm tall.

Palmer amaranth control was visually estimated at 21 DAPRE; 14, 28, and 56 d after POST (DAPOST); and at harvest based on a 0% to 100% scale, with 0% corresponding to no control and 100% corresponding to plant death. A similar scale was used to assess corn injury at 7, 14, and 21 d after PRE and POST herbicide applications, with 0% corresponding to no injury and 100% corresponding to plant death. Palmer amaranth density was assessed from two randomly selected 0.25 m2 quadrats per plot at 21 DAPRE and 28 DAPOST herbicide applications. Aboveground biomass of Palmer amaranth was harvested from the same quadrat areas as used for density data collection at 28 DAPOST, oven-dried at 65 C for 3 days, and weighed. Palmer amaranth density and biomass data were converted into percent density or biomass reduction compared with the nontreated control plots using the following formula (Ganie et al. Reference Ganie, Lindquist, Jugulam, Kruger, Marx and Jhala2017; Sarangi et al. Reference Sarangi, Sandell, Kruger, Knezevic, Irmak and Jhala2017):

(1) $${\rm Biomass}\,\,{\rm or}\,\,{\rm Density}\,\,{\rm reduction}\,\left( \,\&#x0025;\, \right)\,{\equals}\,{{\left( {C{\minus}\left. B \right)} \right.} \over C}{\times}100,$$

where C is the biomass or density of the nontreated control plot, and B is the biomass or density collected from the experimental (herbicide treated) plot. At maturity, corn was harvested from the middle two rows of each plot with a small-plot combine, and weight and moisture content were measured. Corn yields were adjusted to 15.5% moisture content (Ganie et al. Reference Ganie, Lindquist, Jugulam, Kruger, Marx and Jhala2017).

Economic analysis was performed to evaluate the profit and risk associated with each PRE followed by POST herbicide program. Net return from herbicide programs was calculated using the conventional corn yield from each replication and herbicide program cost (Bradley et al. Reference Bradley, Johnson, Hart, Buesinger and Massey2000; Edwards et al. Reference Edwards, Jordan, Owen, Dixon, Young, Wilson, Weller and Shaw2014; Johnson et al. Reference Johnson, Bradley, Hart, Buesinger and Massey2000):

(2) $${\rm Net}\,\,{\rm return}\, {\equals}\,{\rm Gross}\,\,{\rm revenue}{\minus}{\rm Herbicide}\,\,{\rm program}\,\,{\rm cost}{\rm .}$$

Gross revenue was calculated by multiplying the conventional corn yield from each replication for each program by the average grain price ($0.14 kg─1) received in Nebraska at harvest time during the experimental years (USDA-NASS 2016). Each herbicide program cost included the average herbicide cost per hectare obtained from three agricultural chemical dealers in Nebraska and a custom application cost of $18.11 ha─1 application─1.

Statistical Analysis

Palmer amaranth control estimates, net return, density reduction, aboveground biomass reduction, and corn injury and yield data were subjected to ANOVA using the PROC GLIMMIX procedure in SAS version 9.3 (SAS Institute Inc., Cary, NC 27513). Herbicide programs and experimental years were considered fixed effects, whereas replications were considered a random effect in the model. Data were combined over years when there was no year by herbicide program interaction. Year by herbicide program interactions for Palmer amaranth control, density, and biomass reduction were not significant; therefore, data were combined over three years. However, year by herbicide program interaction was significant for corn yield and net return, with no difference between 2015 and 2016; therefore, yield and net return data were combined for 2015 and 2016 and presented separately for 2014. The nontreated control was not included in the data analysis for control estimates and percent density and biomass reduction. Before analysis, data were tested for normality and homogeneity of variance using the Shapiro-Wilk goodness-of-fit and Levene’s tests in SAS. To meet the normality and homogeneity of variance assumption for ANOVA, all data, aside from corn yield, were arcsine square-root transformed before analysis; however, back-transformed data are presented with mean separation based on the transformed data. Where the ANOVA indicated herbicide program effects were significant, means were separated at P≤0.05 with Tukey-Kramer’s pairwise comparison test to reduce type I error for the series of comparisons. Preplanned single degree-of-freedom contrast statements were used to determine relative efficacy of PRE and POST herbicides for Palmer amaranth control, density, and biomass reduction.

Results and Discussion

Palmer Amaranth Control

PS II- and HPPD-inhibitor–resistant Palmer amaranth was controlled 68% to 86% with pyroxasulfone plus fluthiacet-ethyl plus atrazine (1,580 g ha−1), saflufenacil plus dimethenamid-P (390 g ha−1), or mesotrione plus S-metolachlor plus atrazine (2,780 g ha−1) at 21 DAPRE application (Table 3). The contrast analysis suggested that mesotrione plus S-metolachlor plus atrazine applied PRE provided 83% Palmer amaranth control compared to 78%, 72%, and 68% control with pyroxasulfone plus fluthiacet-ethyl plus atrazine, saflufenacil plus dimethenamid-P, and acetochlor, respectively, at 21 DAPRE (Table 4). Similarly, Kohrt and Sprague (Reference Kohrt and Sprague2017) reported 80% to 97% Palmer amaranth control with mesotrione plus S-metolachlor plus atrazine or saflufenacil plus dimethenamid-P at 45 DAPRE. However, Oliveira et al. (Reference Oliveira, Jhala, Gaines, Irmak, Amundsen, Scott and Knezevic2017) reported ≥95% control of HPPD inhibitor–resistant tall waterhemp [Amaranthus tuberculatus (Moq.) Sauer], a species closely related to Palmer amaranth, with mesotrione plus S-metolachlor plus atrazine or pyroxasulfone plus fluthiacet-ethyl plus atrazine at 30 DAPRE in Nebraska. Janak and Grichar (Reference Janak and Grichar2016) reported >95% Palmer amaranth control with PRE applications of saflufenacil plus dimethenamid-P or mesotrione plus S-metolachlor plus atrazine. Aulakh and Jhala (Reference Aulakh and Jhala2015) reported 96% common waterhemp control with PRE application of saflufenacil plus dimethenamid-P at 15 DAPRE. At the research site, poor Palmer amaranth control was observed by the grower with the POST application of PS II- and HPPD-inhibitors in previous years, resulting in high seed additions to the soil seedbank. During the experimental years, a very high density of Palmer amaranth, ranging from 300 to 400 plants m−2, could explain the <85% Palmer amaranth control with PRE herbicides in this study.

Table 3 Effect of herbicide programs on photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth control in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.Footnote a

a Abbreviations: AMS, ammonium sulfate (DSM Chemicals North America Inc., Augusta, GA); fb, followed by; NIS, nonionic surfactant (Induce, Helena Chemical Co., Collierville, TN); POST, postemergence; PRE, preemergence.

b All POST herbicide programs, except acetochlor, were mixed with AMS at 2.5% (wt/v) and NIS at 0.25% (v/v). PRE applications were made within 3 d after planting corn, and POST herbicides were applied when Palmer amaranth was 12 to 15 cm tall.

c Means within columns with no common letter(s) are significantly different according to Tukey-Kramer’s pairwise comparison test (P≤0.05).

d Data from the nontreated control were not included in analysis.

Table 4 Contrast means for control and density reduction of photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth at 21 d after a preemergence application in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.Footnote a

a Single degree-of-freedom contrast analysis; *indicates significance at P<0.05.

b Palmer amaranth density data were converted into percent density reduction compared with the nontreated control using the following formula: ${\rm Density}\,{\rm reduction}\,\left( \,\&#x0025;\, \right)\,{\equals}\,{{\left( {C{\minus}\left. B \right)} \right.} \over C}{\times}100$ , where C is the density of the nontreated control plot and B is the density collected from the experimental plot.

Palmer amaranth control was improved when PRE herbicides were followed by POST herbicides. PRE herbicides followed by POST application of dicamba, dicamba plus diflufenzopyr, or dicamba plus halosulfuron controlled Palmer amaranth 74% to 98% throughout the season (Table 3). Similarly, Oliveira et al. (Reference Oliveira, Jhala, Gaines, Irmak, Amundsen, Scott and Knezevic2017) reported 91% control of HPPD inhibitor–resistant tall waterhemp with mesotrione plus S-metolachlor plus atrazine followed by dicamba plus diflufenzopyr at 32 DAPOST. PRE herbicides followed by acetochlor applied POST provided 26% to 70% Palmer amaranth control throughout the season because acetochlor is a soil residual herbicide and cannot control emerged weeds. Furthermore, most of the Palmer amaranth plants were 12 to 15 cm tall when POST herbicides were applied, resulting in poor control with acetochlor applied POST. Based on contrast analysis, dicamba or dicamba plus diflufenzopyr applied POST provided 88% to 97% Palmer amaranth control compared to 80% to 86% and 44% to 66% control with dicamba plus halosulfuron and acetochlor, respectively, at 14 and 56 DAPOST (Table 5). Similar Palmer amaranth control has been reported in previous studies; for example, Jhala et al. (Reference Jhala, Sandell, Rana, Kruger and Knezevic2014) reported 90% control of PS II- and HPPD-inhibitor–resistant Palmer amaranth with dicamba at 21 DAPOST. A recent study in Tennessee reported 89% control of glyphosate-resistant Palmer amaranth with dicamba plus diflufenzopyr at 28 DAPOST (Crow et al. Reference Crow, Steckel, Mueller and Hayes2016). Kohrt and Sprague (Reference Kohrt and Sprague2017) reported 91% to 94% Palmer amaranth control with dicamba or dicamba plus diflufenzopyr at 14 DAPOST. In addition, Schuster and Smeda (Reference Schuster and Smeda2007) reported >95% common waterhemp control with a 35 DAPOST application of dicamba plus diflufenzopyr. Previous studies have reported increased weed control by tank-mixing diflufenzopyr with dicamba; however, the synergistic effect was species-specific (Grossmann et al. Reference Grossmann, Caspar, Kwiatkowski and Bowe2002; Lym and Deibert Reference Lym and Deibert2005; Wehtje Reference Wehtje2008). There is no published evidence of the synergistic effects of dicamba and diflufenzopyr for Palmer amaranth control.

Table 5 Contrast means for photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth control at 14, 28, and 56 d after POST (DAPOST) and at harvest and for density and biomass reduction at 28 DAPOST in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.Footnote a

a Single degree-of-freedom contrast analysis; asterisk indicates significance at P<0.05.

b Palmer amaranth density and biomass data were converted into percent density or biomass reduction compared with the nontreated control using the following formula: ${\rm Biomass}\,{\rm or}\,{\rm Density}\,{\rm reduction}\,\left( \,\&#x0025;\, \right)\,{\equals}\,{{\left( {C{\minus}\left. B \right)} \right.} \over C}{\times}100,$ where C is the biomass or density of the nontreated control plot and B is the biomass or density collected from the experimental plot.

Palmer Amaranth Density and Shoot Biomass Reduction

Palmer amaranth control results were reflected in Palmer amaranth density and aboveground biomass. PRE herbicides aside from acetochlor (52%) reduced Palmer amaranth density 67% to 86% compared with the nontreated control at 21 DAPRE (Table 6). The contrast analysis suggested that mesotrione plus S-metolachlor plus atrazine provided 81% density reduction compared to 71% to 75% with pyroxasulfone plus fluthiacet-ethyl plus atrazine and saflufenacil plus dimethenamid-P at 21 DAPRE (Table 4). Palmer amaranth density reduction was improved when PRE herbicides were followed by POST herbicides. At 28 DAPOST, 83% to 95% Palmer amaranth density reduction was observed with pyroxasulfone plus fluthiacet-ethyl plus atrazine or mesotrione plus S-metolachlor plus atrazine applied PRE followed by dicamba or dicamba plus diflufenzopyr POST, saflufenacil plus dimethenamid-P followed by dicamba plus diflufenzopyr, or pyroxasulfone plus fluthiacet-ethyl plus atrazine followed by dicamba plus halosulfuron. The remainder of the herbicide programs resulted in 49% to 76% density reduction. Similarly, Oliveira et al. (Reference Oliveira, Jhala, Gaines, Irmak, Amundsen, Scott and Knezevic2017) reported >95% density reduction of HPPD inhibitor–resistant tall waterhemp with mesotrione plus S-metolachlor plus atrazine applied PRE followed by dicamba plus diflufenzopyr applied POST at 32 DAPOST. Based on contrast analysis, POST application of dicamba plus diflufenzopyr provided 85% density reduction compared to 73% to 75% density reduction with dicamba or dicamba plus halosulfuron at 28 DAPOST (Table 5).

Table 6 Effect of herbicide programs on photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth density reduction at 21 d after PRE (DAPRE) and 28 d after POST (DAPOST), biomass reduction at 28 DAPOST, and corn yield in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.Footnote a

a Abbreviations: AMS, ammonium sulfate (DSM Chemicals North America Inc., Augusta, GA); fb, followed by; NIS, nonionic surfactant (Induce, Helena Chemical Co., Collierville, TN); POST, postemergence; PRE, preemergence.

b All POST herbicide programs, except acetochlor, were mixed with AMS at 2.5% (wt/v) and NIS at 0.25% (v/v). PRE applications were made within 3 d after planting corn and POST herbicides were applied when Palmer amaranth was 12 to 15 cm tall.

c Means within columns with no common letter(s) are significantly different according to Tukey-Kramer’s pairwise comparison test (P≤0.05).

d Percent density and biomass reduction data of the nontreated control were not included in analysis. Palmer amaranth density and biomass data were converted into percent density or biomass reduction compared with the nontreated control plots using the following formula: $${\rm Biomass}\,/\,{\rm Density}\,{\rm reduction}\left( \,\&#x0025;\, \right){\equals}{{\left( {C{\minus}\left. B \right)} \right.} \over C}{\times}100,$$ , where C is the biomass or density of the nontreated control plot and B is the biomass or density collected from the experimental plot.

Palmer amaranth aboveground biomass was reduced 73% to 94% with most PRE followed by POST herbicide programs at 28 DAPOST (Table 6). However, PRE herbicides followed by acetochlor applied POST provided 44% to 64% biomass reduction because acetochlor was not able to control emerged weeds. Palmer amaranth biomass reduction observed with the herbicide programs coincides with control and density reduction at 28 DAPOST (Tables 3 and 6). The contrast analysis suggested 79% to 87% Palmer amaranth biomass reduction with POST applications of dicamba, dicamba plus diflufenzopyr, or dicamba plus halosulfuron at 28 DAPOST (Table 5). Similarly, Jhala et al. (Reference Jhala, Sandell, Rana, Kruger and Knezevic2014) reported 73% to 85% biomass reduction of PS II and HPPD inhibitor–resistant Palmer amaranth with POST application of dicamba in Nebraska.

Corn Injury and Yield

No corn injury was observed at 7, 14, and 21 d after PRE or POST herbicide applications in the three year study (data not shown). Previous studies have also reported no corn injury with PRE applications of mesotrione plus S-metolachlor plus atrazine at 1,880 and 2,960 g ha−1 and twice the labeled rate of acetochlor (Chikoye et al. Reference Chikoye, Lum, Ekeleme and Udensi2009; Janak and Grichar Reference Janak and Grichar2016). Ganie et al. (Reference Ganie, Lindquist, Jugulam, Kruger, Marx and Jhala2017) observed 2% to 4% corn injury at 7 DAPRE with saflufenacil plus dimethenamid-P at a rate higher (780 g ha−1) than that applied in this study (390 g ha−1). Some studies also reported minimal to no corn injury with dicamba (600 g ha−1), dicamba plus diflufenzopyr (200 g ha−1), or dicamba plus halosulfuron (380 g ha−1) at 14 DAPOST (Ganie et al. Reference Ganie, Lindquist, Jugulam, Kruger, Marx and Jhala2017; Kohrt and Sprague Reference Kohrt and Sprague2017; Soltani et al. Reference Soltani, Vyn and Sikkema2008). VanGessel et al. (Reference VanGessel, Johnson and Scott2016) reported hybrid corn stunting and leaf chlorosis up to 10% at 7 DAPOST application of dicamba plus diflufenzopyr at twice (588 g ha−1) the labeled rate. Dicamba plus diflufenzopyr is a new safened formulation of dicamba that can be applied to corn plants from 10 cm to 90 cm tall or the 2- to 10-leaf stage (whichever comes first), assuring reduced corn injury (Anonymous 2017c). In contrast, dicamba can be applied to up to 5-leaf or 20-cm-tall corn or at reduced rates later in the season using drop nozzles, also known as a directed spray (Anonymous 2017a). Grossmann et al. (Reference Grossmann, Caspar, Kwiatkowski and Bowe2002) reported reduced absorption of dicamba into corn leaves with the addition of diflufenzopyr, and hence, lower corn injury compared to dicamba applied alone.

Corn yield was comparatively lower in 2014 due to damage from strong winds during rainfall in August. In 2014, corn yield of 4,100 to 6,000 kg ha−1 was achieved from all PRE followed by POST herbicide programs except for mesotrione plus S-metolachlor plus atrazine followed by acetochlor (2,530 kg ha−1). In 2015/2016, all herbicide programs provided similar corn yield of 10,500 to 14,000 kg ha−1, aside from saflufenacil plus dimethenamid-P or mesotrione plus S-metolachlor plus atrazine applied PRE followed by acetochlor applied POST (7,800 to 9,500 kg ha−1) (Table 6). The reduced corn yield with most PRE herbicides followed by POST application of acetochlor could be explained by reduced Palmer amaranth control and density and biomass reduction throughout the season since acetochlor applied POST was not able to control emerged Palmer amaranth plants.

Economic Analysis

The cost of PRE followed by POST herbicide programs ranged from $87.91 to $197.17 ha−1 and provided $1,088 to $1,924 ha−1 gross income from corn yield in 2015/2016 compared to $382 to $836 ha−1 in 2014 (Table 7) because of lower corn yield in 2014 (Table 6) due to damage from strong winds and rain. In 2014 and 2015/2016, PRE followed by POST programs aside from mesotrione plus S-metolachlor plus atrazine followed by acetochlor ($191 and $897) provided net returns of $427 to $707 and $1,127 to $1,727, respectively. Though statistically similar to other programs, PRE herbicides followed by dicamba, dicamba plus diflufenzopyr, or dicamba plus halosulfuron applied POST provided $427 to $707 and $1,398 to $1,727 net returns in 2014 and 2015/2016, respectively.

Table 7 Cost of herbicide programs for controlling photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth in conventional corn and net return from corn yield in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.Footnote a

a Abbreviations: fb, followed by; POST, postemergence; PRE, preemergence.

b All POST herbicide programs except acetochlor were mixed with ammonium sulfate at 2.5% (wt/v) and nonionic surfactant at 0.25% (v/v).

c Program cost includes an average cost of herbicide, ammonium sulfate, and nonionic surfactant, as well as the cost of application ($18.11 ha−1 application−1) from two independent sources in Nebraska.

d Gross revenue was calculated by multiplying the conventional corn yield from each replication for each program by the average grain price ($0.14 kg−1) received in Nebraska at harvest time during the experimental years. Net return was calculated as gross income from conventional corn yield for each replication minus herbicide program cost.

e Means within columns with no common letter(s) are significantly different according to Tukey-Kramer’s pairwise comparison test (P≤0.05).

Practical Implications

Several fields in Nebraska are under GR corn production using glyphosate as a POST herbicide option for weed control (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017; Jhala et al. Reference Jhala, Sandell, Rana, Kruger and Knezevic2014). Studies conducted at the research site indicate that PS II- and HPPD-inhibitor–resistant Palmer amaranth was sensitive to glyphosate since this herbicide was not applied over the past eight years as the field was kept under conventional seed corn production (data not shown). However, because of the evolution and occurrence of GR Palmer amaranth and other GR weeds in Nebraska (Chahal et al. Reference Chahal, Varanasi, Jugulam and Jhala2017; Heap Reference Heap2017), glyphosate should not be considered as a single management option. Results of this study indicate that Palmer amaranth can be effectively controlled without glyphosate using PRE followed by POST herbicides with different sites of action. In addition, economic analysis suggests that the use of distinct sites of action PRE herbicides followed by POST application of dicamba-based herbicides tested in this study provided higher gross income and net returns. However, there is an urgent need to adopt an integrated weed management approach that includes the use of a different sites of action PRE followed by POST herbicide program, crop rotation, the rotation of different HR cultivars with conventional crop cultivars, tillage, and harvest weed seed control methods to mitigate the evolution and spread of multiple HR Palmer amaranth.

Acknowledgements

The authors acknowledge Irvin Schleufer, Jatinder Aulakh, Mason Adams, Ian Rogers, Debalin Sarangi, and Zahoor Ganie for their help in this project. Partial funding from Nebraska Corn Board is greatly appreciated.

References

Anonymous (2017a) Clarity Herbicide Specimen Label. http://www.cdms.net/ldat/ld797012.pdf Google Scholar
Anonymous (2017c) Status Herbicide Specimen Label. http://www.cdms.net/ldat/ld0K2001.pdf Google Scholar
Aulakh, JS, Jhala, AJ (2015) Comparison of glufosinate-based herbicide programs for broad-spectrum weed control in glufosinate-resistant soybean. Weed Technol 29:419430 Google Scholar
Bollman, JD, Boerboom, CM, Becker, RL, Fritz, VA (2008) Efficacy and tolerance to HPPD-inhibiting herbicides in sweet corn. Weed Technol 22:666674 Google Scholar
Bradley, PR, Johnson, WG, Hart, SE, Buesinger, ML, Massey, RE (2000) Economics of weed management in glufosinate-resistant corn (Zea mays L.). Weed Technol 14:495501 CrossRefGoogle Scholar
Chahal, PS, Varanasi, VK, Jugulam, M, Jhala, AJ (2017) Glyphosate-resistant Palmer amaranth (Amaranthus palmeri) in Nebraska: confirmation, EPSPS gene amplification, and response to POST corn and soybean herbicides. Weed Technol 31:8093 Google Scholar
Chikoye, D, Lum, AF, Ekeleme, F, Udensi, U (2009) Evaluation of Lumax® for preemergence weed control in maize in Nigeria. Int J Pes Manag 55:275283 Google Scholar
Crow, WD, Steckel, LE, Mueller, TC, Hayes, RM (2016) Management of large glyphosate-resistant Palmer amaranth in corn. Weed Technol 30:611616 CrossRefGoogle Scholar
Edwards, CB, Jordan, DL, Owen, MDK, Dixon, PM, Young, BG, Wilson, RG, Weller, SC, Shaw, DR (2014) Benchmark study on glyphosate-resistant crop systems in the United States. Economics of herbicide resistance management practices in a 5 year field-scale study. Pest Manag Sci 70:19241929 Google Scholar
Fleming, AA, Banks, PA, Legg, JG (1988) Differential response of maize inbreds to bentazon and other herbicides. Can J Plant Sci 68:501507 Google Scholar
Ganie, ZA, Jhala, AJ (2017) Glyphosate-resistant common ragweed (Ambrosia artemisiifolia) in Nebraska: confirmation and response to postemergence corn and soybean herbicides. Weed Technol 31:225237 Google Scholar
Ganie, ZA, Lindquist, JL, Jugulam, M, Kruger, GR, Marx, DB, Jhala, AJ (2017) An integrated approach to control glyphosate resistant Ambrosia trifida with tillage and herbicides in glyphosate-resistant maize. Weed Res 57:112122 Google Scholar
Grossmann, K, Caspar, G, Kwiatkowski, J, Bowe, SJ (2002) On the mechanism of selectivity of the corn herbicide BAS 662H: a combination of the novel auxin transport inhibitor diflufenzopyr and the auxin herbicide dicamba. Pest Manag Sci 58:10021014 CrossRefGoogle ScholarPubMed
Hall, M, Swanton, CJ, Anderson, GW (1992) The critical period of weed control in corn (Zea mays). Weed Sci 40:441447 CrossRefGoogle Scholar
Heap, I (2017) Herbicide Resistant Palmer Amaranth Globally. http://www.weedscience.org/Summary/Species.aspx Google Scholar
Janak, TW, Grichar, WJ (2016) Weed control in corn (Zea mays L.) as influenced by preemergence herbicides. Int J Agron 2016:2607671. doi: 10.1155/2016/2607671 Google Scholar
Jhala, AJ, Sandell, LD, Rana, N, Kruger, GR, Knezevic, SZ (2014) Confirmation and control of triazine and 4-hydroxyphenylpyruvate dioxygenase-inhibiting herbicide-resistant Palmer amaranth (Amaranthus palmeri) in Nebraska. Weed Technol 28:2838 Google Scholar
Johnson, WG, Bradley, PR, Hart, SE, Buesinger, ML, Massey, RE (2000) Efficacy and economics of weed management in glyphosate-resistant corn (Zea mays). Weed Technol 14:5765 Google Scholar
Kohrt, JR, Sprague, CL (2017) Herbicide management strategies in field corn for a three-way herbicide-resistant Palmer amaranth (Amaranthus palmeri) population. Weed Technol 31:364372 Google Scholar
Lym, RG, Deibert, KJ (2005) Diflufenzopyr influences leafy spurge (Euphorbia esula) and Canada thistle (Cirsium arvense) control by herbicides. Weed Technol 19:329341 CrossRefGoogle Scholar
Norsworthy, JK, Ward, SM, Shaw, DR, Llewellyn, RS, Nichols, RL, Webster, TM, Bradley, KW, Frisvold, G, Powles, SB, Burgos, NR, Witt, WW, Barrett, M (2012) Reducing the risks of herbicide resistance: best management practices and recommendations. Weed Sci (Spec Issue I) 60:3162 Google Scholar
[NWS-COOP] The National Weather Service Cooperative Observer Program (2017) Cooperative Observer Program. http://www.weather.gov/rah/coop Google Scholar
Oliveira, MC, Jhala, AJ, Gaines, T, Irmak, S, Amundsen, K, Scott, JE, Knezevic, SZ (2017) Confirmation and control of HPPD-inhibiting herbicide–resistant waterhemp (Amaranthus tuberculatus) in Nebraska. Weed Technol 31:6779 Google Scholar
Reddy, KN, Nandula, VK (2012) Herbicide resistant crops: history, development and current technologies. Indian J Agron 57:17 Google Scholar
Rice, CA, Mesbah, A, Miller, SD (2001) Economic evaluation of weed management systems in sugarbeets. Proc Am Soc Sugar Beet Tech 31:64 Google Scholar
Sarangi, D, Sandell, LD, Knezevic, SZ, Aulakh, JS, Lindquist, JL, Irmak, S, Jhala, AJ (2015) Confirmation and control of glyphosate-resistant common waterhemp (Amaranthus rudis) in Nebraska. Weed Technol 29:8292 CrossRefGoogle Scholar
Sarangi, D, Sandell, LD, Kruger, GR, Knezevic, SZ, Irmak, S, Jhala, AJ (2017) Comparison of herbicide programs for season-long control of glyphosate-resistant common waterhemp (Amaranthus rudis) in soybean. Weed Technol 31:5366 CrossRefGoogle Scholar
Sauer, JD (1957) The grain amaranths and their relatives: a revised taxonomic and geographic survey. Ann MO Bot Gard 54:101113 Google Scholar
Schuster, CL, Smeda, RJ (2007) Management of Amaranthus rudis S. in glyphosate-resistant corn (Zea mays L.) and soybean (Glycine max L. Merr.). Crop Prot 26:14361443 Google Scholar
Soltani, N, Vyn, JD, Sikkema, PH (2008) Control of common waterhemp (Amaranthus tuberculatus var. rudis) in corn and soybean with sequential herbicide applications. Can J Plant Sci 89:127132 Google Scholar
Swanton, CJ, Gulden, RH, Chandler, K (2007) A rationale for atrazine stewardship in corn. Weed Sci 55:7581 Google Scholar
[USDA-NASS] U.S. Department of Agriculture National Agricultural Statistics Service (2016) Quick Stats. https://quickstats.nass.usda.gov/ Google Scholar
[USDA-NASS] U.S. Department of Agriculture National Agricultural Statistics Service (2017) Prospective plantings. http://usda.mannlib.cornell.edu/usda/current/ProsPlan/ProsPlan-03-31-2017.pdf Google Scholar
VanGessel, MJ, Johnson, QR, Scott, BA (2016) Evaluating postemergence herbicides, safener, and tolerant hybrids for corn response. Weed Technol 30:869877 Google Scholar
Wehtje, G (2008) Synergism of dicamba with diflufenzopyr with respect to turfgrass weed control. Weed Technol 22:679684 Google Scholar
Figure 0

Table 1 Monthly mean air temperature and total precipitation during the 2014, 2015, and 2016 growing seasons and 30-year averages at Shickley, Nebraska.a

Figure 1

Table 2 Herbicide products, rates, and application timing for control of photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.a

Figure 2

Table 3 Effect of herbicide programs on photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth control in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.a

Figure 3

Table 4 Contrast means for control and density reduction of photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth at 21 d after a preemergence application in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.a

Figure 4

Table 5 Contrast means for photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth control at 14, 28, and 56 d after POST (DAPOST) and at harvest and for density and biomass reduction at 28 DAPOST in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.a

Figure 5

Table 6 Effect of herbicide programs on photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth density reduction at 21 d after PRE (DAPRE) and 28 d after POST (DAPOST), biomass reduction at 28 DAPOST, and corn yield in conventional corn in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.a

Figure 6

Table 7 Cost of herbicide programs for controlling photosystem II- and 4-hydroxyphenylpyruvate dioxygenase-inhibitor–resistant Palmer amaranth in conventional corn and net return from corn yield in field experiments conducted at Shickley, Nebraska in 2014, 2015, and 2016.a