Plant Materials and Growing Conditions

The KCTR A. palmeri population reported to have evolved resistance to 2,4-D and MCPA (Shyam et al. Reference Shyam, Borgato, Peterson, Dille and Jugulam2021) was used in this study. Two known MCPA-susceptible populations MSS (Mississippi) and KSS (Kansas) were also used for comparison. All experiments were conducted in the greenhouse and/or controlled-environment growth-chamber facilities. The greenhouse was maintained at 32/23 ± 2 C day/night temperatures, 60 ± 10% relative humidity, and 15/9-h day/night photoperiod provided with sodium vapor lamps delivering 500 μmol m⁻² s⁻¹ illumination at canopy level, while the growth chambers were maintained at 32/22 C day/night temperatures and 60 ± 10% relative humidity, with a 16/8 day/night photoperiod, provided by incandescent and fluorescent bulbs delivering 600 μmol m⁻² s⁻¹ illumination at plant canopy level. All three populations were raised in the greenhouse from seeds in trays (21 by 6 by 4 cm). The MSS, KSS, and KCTR A. palmeri seeds were planted, and upon germination, seedlings at the cotyledon stage were transplanted to individual pots (6 by 6 by 6.5 cm) containing commercial pre-mix (Pro-Mix^® premium potting mix, Premier Tech Home and Garden, Mississauga, ON, Canada). The seedlings (6- to 8-cm height) were transferred to the growth chambers to acclimatize.

MCPA Dose–Response Experiments

Amaranthus palmeri plants (MSS, KSS, and KCTR) at 10- to 12-cm height (2- to 3-wk old), were treated with MCPA (MCPA-ester 4^®, Albaugh, Iowa, USA) at 0 (nontreated [NT]), 70, 140, 280, 560 (label recommended, i.e., 1× dose), 1,120, and 2,240 g ae ha⁻¹, using a bench-type sprayer (Research Track Sprayer, De Vries Manufacturing, Hollandale, MN, USA) fitted with a single flat-fan nozzle (8002 TeeJet^® tip, Spraying Systems, Wheaton, IL, USA) that delivers 187 L ha⁻¹ in a single pass of 4.85 km h⁻¹ at 207 kPa pressure. Treated seedlings were transferred back to the growth chamber after 45 min of MCPA application. Amaranthus palmeri plants were watered daily as required. Visual injury ratings (VIR; 0 to 100) were recorded every week, up to 3 wk after treatment (WAT), with 0 (no herbicide injury) and 100 (dead plant) compared with NT plants. At 3 WAT, aboveground plant parts were harvested separately, placed in brown paper bags, and dried in an oven at 65 C for 72 h. Individual plant dry biomass was weighed. The relative dry biomass was determined as a percent of NT using Equation 1:

([1]) $${\rm{RDW\;}} = \left( {{{{\rm{DW}}} \over {{\rm{\;ADW\;}}}}} \right) \times 100$$

In Equation 1, RDW is the relative dry weight as percentage of NT, DW is the dry weight of the individual plant (in grams), and ADW is the average dry weight of NT (in grams).

Absorption and Translocation of [¹⁴C]MCPA in KCTR and MSS Amaranthus palmeri

There was no statistical difference between MSS and KSS Palmer amaranth regarding their response to the 1× dose of MCPA. However, MSS plants exhibited more injury than KSS plants at the 1× dose of MCPA (Figure 1); MSS plants were therefore used for subsequent experiments for comparison with KCTR plants.

Figure 1. Response of MSS, KSS, and KCTR Amaranthus palmeri to seven doses of MCPA at 3 wk after treatment (WAT). 1× is the field recommended dose of MCPA (560 g ha⁻¹). MSS, MCPA-susceptible population from Mississippi; KSS, MCPA-susceptible population from Kansas; KCTR, 2,4-D- and MCPA-resistant population from Kansas.

MSS and KCTR A. palmeri seedlings were grown as described earlier, and 10- to 12-cm- height plants were used. A stock solution containing ¹⁴C-radiolabeled MCPA (Moravek, Brea, CA, USA) mixed with commercial MCPA was prepared to obtain the equivalent to the field recommended dose (560 g ha⁻¹) in a carrier volume of 187 L ha⁻¹. Each plant was treated with 10 μl of stock solution of [¹⁴C]MCPA, with total radioactivity of 0.083 kBq μl⁻¹ (5,000 dpm μl⁻¹), on the adaxial surface of the third or fourth fully opened leaf in the form of small 1-μl droplets with the help of a pipette. The treated plants were transferred back to the growth chamber 20 min after the treatment. Plant tissue was harvested separately as treated leaf (TL), above treated leaf (ATL), and below treated leaf (BTL) at 24 and 48 h after treatment (HAT). The TL was washed twice with 5 ml of wash solution (10% v/v ethanol with 0.5% v/v Tween-20; BFC Chemicals, Wilmington, DE, USA) for 1 min in 20-ml scintillation vials. The rinsate was mixed with 10 ml of scintillation cocktail (EcoLite(+)™, MP Biomedicals, Solon, OH, USA) and the total radioactivity was recorded using a liquid scintillation counter (LSC; LS6500 Liquid Scintillation Counter, Beckman Coulter, Brea, CA, USA). ATL, TL, and BTL plant tissues were wrapped separately in wipes (Kimwipes^®, Kimberley-Clark, Roswell, GA, USA), oven-dried at 60 C for 72 h, and then combusted using a biological oxidizer (OX-501, RJ Harvey Instruments, Tappan, NY, USA). Evolved CO₂ was trapped in a ¹⁴C trapping cocktail (Carbon14 (C-14) cocktail, Z Scientific, New City, NY, USA). The radioactivity was recorded with the help of LSC. LSC data were converted to percent herbicide absorbed and translocated using following equations (Equations 2 to 6):

([2]) $${\rm{Abs}}.{\rm{ }}\left( \% \right){\rm{ }} = {\rm{ }}\left[ {\left( {{{\rm{R}}_{{\rm{Applied}}}}-{\rm{ }}{{\rm{R}}_{{\rm{Rinsate}}}}} \right)/{{\rm{R}}_{{\rm{Applied}}}}} \right] \times 100$$

([3]) $${\rm{Trans}}.{\rm{ }}\left( \% \right) = 100-\left[ {{{\rm{R}}_{{\rm{TL}}}}/\left( {{{\rm{R}}_{{\rm{Applied}}}}-{{\rm{R}}_{{\rm{Rinsate}}}}} \right) \times 100} \right]$$

([4]) $${\rm{TL}}\left( \% \right) = {{\rm{R}}_{{\rm{TL}}}}/\left( {{{\rm{R}}_{{\rm{Applied}}}}-{{\rm{R}}_{{\rm{Rinsate}}}}} \right) \times 100$$

([5]) $${\rm{ATL}}\left( \% \right) = {{\rm{R}}_{{\rm{ATL}}}}/\left( {{{\rm{R}}_{{\rm{Applied}}}}-{{\rm{R}}_{{\rm{Rinsate}}}}} \right) \times 100$$

([6]) $${\rm{BTL}}\left( \% \right) = {{\rm{R}}_{{\rm{BTL}}}}/\left( {{{\rm{R}}_{{\rm{Applied}}}}-{{\rm{R}}_{{\rm{Rinsate}}}}} \right) \times 100$$

In these equations, R_Applied is the amount of radioactivity applied (in disintegrations per minute [dpm]), R_Rinsate is the radioactivity of wash solution (in dpm), Abs. (%) is the percentage absorbed, Trans. (%) is the percentage translocated, TL (%) is the percentage of radioactivity recovered from treated leaf, ATL (%) is the percentage of radioactivity recovered from plant parts above the treated leaf, BTL (%) is the percentage of radioactivity recovered from plant parts below the treated leaf.

Metabolism of [¹⁴C]MCPA in KCTR and MSS Amaranthus palmeri

Along with KCTR and MSS A. palmeri, winter wheat ‘KS Western Star’ (WS) plants were also used as a positive control, because of wheat’s ability to metabolize MCPA naturally (Cole and Loughman Reference Cole and Loughman1983). KCTR and MSS seedlings were grown as described earlier. WS seeds of wheat were germinated on filter paper and later transplanted to individual pots filled with pre-mix. Each plant was treated with 10 μl of stock solution of [¹⁴C]MCPA, with total radioactivity of 0.13 kBq μl⁻¹ (8,000 dpm μl⁻¹), on the adaxial surface of the third or fourth fully opened leaf for A. palmeri and the second fully opened leaf for wheat plants in the form of small droplets (1 μl) with the help of a pipette. The treated plants were transferred back to the growth chamber 20 min after the treatment. Aboveground plant tissue of KCTR, MSS A. palmeri, and wheat plants was harvested at 12 HAT, and additionally for KCTR and MSS plants at 24 HAT. The TL was harvested separately and washed as described earlier. The whole plant tissue (aboveground plant parts plus the TL) was wrapped in aluminum foil and immediately frozen in liquid nitrogen. Each sample was then homogenized with a pestle in a mortar and transferred to 15 ml of 90% (v/v) acetone in 50-ml centrifuge tubes to extract the parent [¹⁴C]MCPA and its metabolites. This solution was kept at 4 C for at least 16 h and then centrifuged at 5,000 × g for 10 min. The supernatant was transferred to a new centrifuge tube and concentrated to a volume of 500 to 1,000 μl with the help of a rotary evaporator (Centrivap, Labconco, Kansas City, MO, USA) at 45 C for 90 min. The supernatant was transferred to 2-ml microcentrifuge tubes and centrifuged at 10,000 × g for 10 min. A 90-μl injection of the final supernatant was run through a reverse-phase high-performance liquid chromatograph (1260 Infinity II LC System, Agilent, Santa Clara, CA, USA) to analyze the parent MCPA and the associated metabolites.

Assessment of the Possible Role of P450 in Metabolism of MCPA in KCTR Amaranthus palmeri

Malathion (Spectracide^® Malathion Insect Spray Concentrate, United Industries, St Louis, MO, USA), a known P450 inhibitor was used to assess the ability of P450 enzymes to metabolize MCPA in A. palmeri. Malathion can help minimize herbicide metabolism mediated by P450 activity (Siminszky et al. 2006). Malathion was sprayed at 1,500 g ai ha⁻¹, 30 min before MCPA application, followed by soil drenching with 50 ml of a 5 mM solution of malathion at 24 h following MCPA application. All spray applications were done as described earlier for the dose–response experiments. The VIR and RDW were recorded at 3 WAT as described earlier for the dose–response experiments.

Experimental Designs and Data Analysis

The MCPA dose–response and uptake, translocation, and metabolism experiments were conducted in a randomized complete block design with four replications of each treatment. The P450-inhibitor experiment was conducted according to a factorial design with two A. palmeri populations (KCTR and MSS), three doses of MCPA (0, 560, and 1,120 g ae ha⁻¹), two doses of malathion (0 and 1,500 g ai ha⁻¹), and five replications of each treatment. All experiments were repeated once. Data were analyzed in RStudio using Levene’s test for homogeneity of two runs, and data that were not significantly different were pooled from the two runs of experiments. Pooled data for relative dry weight (as % NT) were analyzed using a three-parameter log-logistic regression mode with the drc package in RStudio (Knezevic et al. Reference Knezevic, Streibig and Ritz2007; Ritz et al. Reference Ritz, Baty, Streibig and Gerhard2015). The following three-parameter regression model was fit (Equation 7):

([7]) $$Y = d + \exp \left[ {b\left( {{\rm{log}}x - e} \right)} \right]{\rm{\;\;\;}}$$

In the equation, $Y$ is the response variable (i.e., relative dry weight); $x$ is the applied MCPA dose; $d$ is the upper limit; $b$ is the relative slope around $e$ ; and $e$ is GR₅₀, which is the dose of herbicide required for 50% biomass reduction.

For the uptake and translocation experiments, the total percentage of absorbed MCPA was determined as percentage applied, whereas the percentage of MCPA translocation was presented as percentage of parent herbicide absorbed (Equations 2 to 6). High-performance liquid chromatography (HPLC) chromatograms represent the concentration of parent MCPA and its metabolites within the plant system. Means were separated using Tukey’s honest significant difference (HSD) test at a significance level of $ \propto = 0$ .05.