Design, Synthesis, and Evaluation of Novel Auxin Mimic Herbicides

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Design, Synthesis and Evaluation of Novel Auxin Mimic Herbicides Chi-Linh Do-Thanh, Jose J. Vargas, Joseph W Thomas, Gregory R. Armel, and Michael D. Best J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.6b00675 • Publication Date (Web): 17 Apr 2016 Downloaded from http://pubs.acs.org on April 26, 2016

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Journal of Agricultural and Food Chemistry

Design, Synthesis and Evaluation of Novel Auxin Mimic Herbicides Chi-Linh Do-Thanh,1 Jose J. Vargas,2 Joseph W.Thomas,2 Gregory R. Armel2,3* and Michael D. Best*1 1

Department of Chemistry, the University of Tennessee, Knoxville, TN 37996 Department of Plant Sciences, the University of Tennessee, Knoxville, TN 37996 3 Global Herbicide Development Division, BASF Corporation, Research Triangle Park, NC 27709 2

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Design, Synthesis and Evaluation of Novel Auxin Mimic Herbicides Chi-Linh Do-Thanh,1 Jose J. Vargas,2 Joseph W.Thomas,2 Gregory R. Armel2,3* and Michael D. Best*1 1

Department of Chemistry, the University of Tennessee, Knoxville, TN 37996 Department of Plant Sciences, the University of Tennessee, Knoxville, TN 37996 3 Global Herbicide Development Division, BASF Corporation, Research Triangle Park, NC 27709 2

* Phone: (865) 974-8658 Fax: (865) 974-9332 E-mail: [email protected]

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ABSTRACT:

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Due to the key roles of auxins as master regulators of plant growth, there is

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considerable interest in the development of compounds with auxin-like properties for

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growth management and weed control applications. Herein, we describe the design and

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multi-step synthesis of ten compounds bearing combinations of functional groups

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commonly associated with auxin-type properties. Following synthesis, these compounds

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were tested against multiple weed species as well as sweet corn. In general, while

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these structures were not quite as active as commercial auxin mimic herbicides,

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multiple compounds exhibited broadleaf weed activity with concurrent selectivity in

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sweet corn. In addition, differential results were observed upon subtle changes to

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structure, providing insights into the structural properties required for activity.

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KEYWORDS: auxins, weed science, synthesis, plant growth

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INTRODUCTION

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Auxins are an important class of plant growth substances called phytohormones

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that play essential roles in many growth and behavioral processes in a plant’s life cycle.

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There are four natural auxins that are synthesized by plants (Figure 1): indole-3-acetic

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acid (IAA), indole-3-butyric acid (IBA), 4-chloroindole-3-acetic acid (4-Cl-IAA), and

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phenylacetic acid (PAA).1 Since IAA influences almost every part of plant growth and

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development, it is believed to act as a “master hormone” in the network of interactions

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with other phytohormones.2 In general, auxins regulate cell division, elongation, and

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developmental processes, which include vascular tissue and floral meristem

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differentiation, leaf initiation, phyllotaxy, senescence, apical dominance, and root

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formation.3

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The stability and concentration of natural auxins is regulated by the plant through

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synthesis, conjugation, and degradation via multiple pathways.4

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concentrations, growth and developmental activities are stimulated, while at high

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concentration, growth is interrupted, and the plant is lethally damaged. As a result,

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there has been considerable interest in the chemical manipulation of the auxin system

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via synthetic analogs in order to study auxin function.5 In the 1940s, various derivatives

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of IAA were synthesized that exhibited auxin-like properties.

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naphthalene acetic acid (1-NAA, Figure 1), 2-methyl-4-chlorophenoxyacetic acid

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(MCPA), and 2,4-dichlorophenoxyacetic acid (2,4-D).6 They produce the same plant

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responses as IAA but are more durable and effective because they are not rendered

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inactive by the plant as rapidly as the endogenous auxins.7 4

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At low auxin

These included 1-

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Synthetic auxin mimics have found practical use not only as growth regulators for

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improving yields in agriculture and horticulture,8 and as media components in tissue

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culture and plant micropropagation,9 but also as herbicides to control weeds.6 MCPA

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and 2,4-D launched a new era of weed control in modern agriculture after being

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introduced to the worldwide market after World War II.

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chemistry have been commercially produced as herbicides. These include the benzoic

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acids, the phenoxy-carboxylic acids, the pyridine-carboxylic acids, the pyrimidine-

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carboxylic acids, and the quinolone-carboxylic acids.

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chemical structure appears to need a strong negative charge on a carboxylic acid group

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that is separated by a distinct distance from a weaker positive charge on an aromatic

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ring.10 When used as herbicides, synthesized auxins mimic the growth-inhibiting effects

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as those caused by IAA applied at high concentrations, which is also observed in

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transgenic, IAA-overproducing plants.11 This occurrence has been described as an

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“auxin overdose,” which is an effect of greater-than-optimal endogenous auxin

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concentrations, causing an imbalance in auxin homeostasis and interactions with other

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hormones in the tissue.7

In fact, multiple classes of

To possess auxin activity, a

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More recent research in auxin mimic herbicides has uncovered more potent

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inhibitors with greater activity on more weed species at lower use rates. These newer

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herbicides contain a carboxylic acid and halogen (primarily chlorine and fluorine)

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substitutions on pyridine or pyrimidine like other auxin mimic herbicides, but these

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compounds are different due to a para-chlorophenyl substituent at the 4-position of the

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heterocyclic ring.12-14 Currently, no research has been presented as to whether this 5

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para-chlorophenol substituent would be efficacious if added to benzyl or indole ring

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structure. Therefore, the objectives of this research were to 1) synthesize benzyl and

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indole ring structures containing a carboxylic acid, at least one halogen, and a para-

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chlorophenol substituent and 2) to evaluate these new compounds for weed control and

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safety to sweet corn (Zea mays L. var. saccharum) in comparison to the commercial

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auxin standards of aminocyclopyrachlor, dicamba, and quinclorac.

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MATERIALS AND METHODS

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Chemicals

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Dicamba (forumulated as Clarity) and quinoclorac (formulated as Drive) were obtained

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from the BASF Corporation and used as received. Aminocyclopyrachlor (DPX-MAT28,

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formulated as a 50% active granule) was obtained from DuPont Crop Protection.

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Starting materials and reagents for synthetic procedures were obtained from Fisher

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Scientific or Aldrich Chemical and used as received.

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General experimental

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a Pure solvent delivery system purchased from Innovative Technology, Inc. Column

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chromatography was performed using 230−400 mesh silica gel purchased from Sorbent

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Technologies. NMR spectra were obtained using Varian Mercury Vx 300 MHz or Bruker

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AC 250 MHz spectrometers.

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Compound evaluation for weed control

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Greenhouse trials were established at the University of Tennessee (35.98 N,

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83.91W) to evaluate the herbicidal activity of the synthesized compounds. Herbicidal

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response of the compounds was evaluated on sweet corn, large crabgrass (Digitaria 6

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sanguinalis), field bindweed (Convolvulus arvensis), barnyardgrass (Echinochloa crus-

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gali), velvetleaf (Abutilon theophrasti), and redroot pigweed (Amaranthus retroflexus).

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These specific weed species were selected in order to provide a mix of common small

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and large seeded monocot and dicot species. Four sweet corn seeds were planted in

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the middle of 23 cm diameter greenhouse pots (XAM09000, Dillen Products/Myers

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Industries Inc., Middlefield, OH) containing a potting media (Pro-Mix BX Mycorrhizae,

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Premier Tech Horticulture Inc., Quakertown, PA). Weed species were shallowly seeded

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around the margin of each greenhouse pot. Plants germinated and were allowed to

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grow for 12 days before application of experimental compounds. On the dates of

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application corn plants were approximately 15 cm in height. Weed species height

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ranged from 3 to 6 cm. Following these herbicide applications, plants were watered

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daily, fertilized as needed, and were augmented with artificial lights as needed to

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maintain adequate day length.

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Compounds were dissolved in 3 mL of acetone before being added to 32 mL of

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deionized water and agitated by hand to form a spray solution. Crop oil concentrate was

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added to the spray solution to form a 1% v/v solution used for each treatment (Agridex,

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Helena Chemical Corp., Memphis, TN). Spray solutions were agitated again before

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application to the plant species using an enclosed sprayer chamber (Generation III track

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sprayer. DeVries Manufacturing, Hollandale, Minnesota) at 215 L ha-1 through an 8004

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EVS nozzle (TeeJet, Wheaton, Illinois). All compounds were applied at a rate of 500 g

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ha-1. Herbicidal activity was quantified by visually measuring injury to each plant species

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10 days after treatment on a 0 (i.e., no injury) to 100 % (i.e., complete plant death) scale

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relative to a non-treated check.

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RESULTS AND DISCUSSION

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The goal of this research was to develop novel auxin mimic herbicides through

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the design and chemical synthesis of structures with similar properties to known auxin

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herbicides, followed by evaluation of herbicidal activities alongside three commercial

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herbicides, aminocyclopyrachlor,15 dicamba,16 and quinclorac17 (Figure 2). Overall, ten

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compounds were synthesized and evaluated for auxin herbicidal activity (1-7).

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The initial set of compound targets is shown in Figure 3A-C, each of which

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contains a para-chlorophenyl group fused to an aromatic unit bearing a carboxylic acid

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as well as different combinations of heteroatoms within the ring. These compounds

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were synthesized through a general scheme by converting commercially available

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carboxylic acids 8a-b, 11a-b, and 14a-b, to methyl esters 9a-b, 12a-b, and 13a-b,

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respectively. This was followed by reaction with 4-chlorophenylboronic acid via a Suzuki

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coupling to attach a chlorophenyl group of 10a-b, 13a-b, and 16a-b,18 and then ester

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hydrolysis in base to restore the carboxylic acid functionality of target compounds 1a-b,

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2a-b, and 3a-b.

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A similar process was used to access target compounds 4-5, which also contain

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a para-chlorophenyl fused to different functionalized benzoic acid moieties (Figure 4A-

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C). To synthesize 4, commercially available carboxylic acid 17 was first converted to

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methyl ester 18. Next, the phenolic moiety of 18 was protected with a para-

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methoxybenzyl (PMB) group to produce intermediate 19, which was coupled to 48

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chlorobronic acid to 20, followed by PMB deprotection to 21 and ester hydrolysis to

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access 4. For the synthesis of 5, compound 22 was first subjected to nitration and

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esterification to form 23, followed by reduction of the nitro group to the amine

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functionality of 24. Finally Suzuki coupling to 27 and ester hydrolysis produced target

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compound 5.

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For the next set of compounds, we fused the para-chlorophenyl group that has been

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effective in prior auxin herbicides to the indole acid moiety of natural auxins (Figure 5).

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Here, compounds 6-7 were accessed through general schemes through the

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esterification of carboxylic acids 26 and 29 to 27 and 30, Suzuki coupling to 28 and 31,

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and ester hydrolysis to 6 and 7, respectively.

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Following the synthesis of the desired compounds, the herbicidal activities of

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these structures next evaluated in plant bioassays. The synthesized molecules were

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applied in the form of a spray solution to six different common weeds (redroot pigweed,

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velvetleaf, field bindweed, barnyardgrass, large crabgrass, and yellow nutsedge) as well

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as sweet corn. An ideal herbicide would be highly active against all the weeds but show

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little to no activity against crops such as corn. Most auxin herbicides typically have their

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greatest activity against dicot weeds as opposed to monocots. This differentiated

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selectivity has allowed auxin mimics to be used in monocot crops for the control of dicot

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weeds. However, quinoline-carboxylic acid auxin herbicides like quinclorac and the new

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6-aryl-picolinate herbicides do maintain some herbicidal activity on key monocot grass

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and sedge species12,19. The commercial auxin mimic herbicides aminocyclopyrachlor,

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dicamba, and quinclorac were tested alongside the newly synthesized compounds

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(Figure 2).

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Out of the synthetic compounds, 2-chlorobenzoic acid 1a provided the greatest

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level of activity, with about 90% control of pigweed, and only 2% injury to corn (Table 1).

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In addition, 1a controlled velvetleaf 58%, however all other species were controlled by

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this analog 30% or less. Small substitution changes to 1a changed weed control,

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especially on redroot pigweed. For example, introduction of the fluorine instead of a

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chlorine on the benzoic acid ring of analog 1b diminished redroot pigweed and

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velvetleaf to 55 and 10%, respectively. A simple introduction of nitrogen into the 6-

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position of the benzoic acid ring in compound 2b drastically reduced redroot pigweed to

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53%, but velvetleaf control declined to only 43%.

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nitrogen placed in the ring at the 3-position reduced control of both redroot pigweed and

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velvetleaf to 3% or less. Curiously, the addition of an amine in the meta position relative

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to both the carboxylic acid and chlorophenyl groups in analog 5 reduced redroot

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pigweed and velvetleaf to 40% and 17%, respectively. Several potent commercial auxin

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mimic herbicides contain amine group substitutions in a similar position (e.g.,

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aminopyralid, picloram, aminocylclopyrachlor, and halauxifen). In many instances these

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amine substituted compounds are more potent when compared to similar auxin mimics

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that lack this substitution.12

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modest activity (