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Plant growth regulators differentially suppress goosegrass and smooth crabgrass in creeping bentgrass turf

Published online by Cambridge University Press:  23 May 2024

John M. Peppers
Affiliation:
Graduate Research Assistant, School of Plant and Environmental Sciences, Virginia Polytechnic Institute and State University, Blacksburg, VA, USA
J. Scott McElroy
Affiliation:
Professor, Department of Crop Soil and Environmental Sciences, Auburn University, Auburn, AL, USA
Shawn D. Askew*
Affiliation:
Professor, School of Plant and Environmental Sciences, Virginia Polytechnic Institute and State University, Blacksburg, VA, USA
*
Corresponding author: Shawn Askew; Email: [email protected]
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Abstract

Goosegrass and smooth crabgrass in creeping bentgrass turf are difficult to control due to a lack of selective herbicides. Based on preliminary field observations, we hypothesized that paclobutrazol and flurprimidol would reduce the overall competitiveness of goosegrass and smooth crabgrass in creeping bentgrass. Greenhouse and field studies were designed to evaluate the effect of several plant growth regulators (PGRs) on goosegrass and smooth crabgrass competitive indices. In greenhouse studies, flurprimidol, paclobutrazol, trinexapac-ethyl, and prohexadione-calcium were applied either preemergence only or preemergence plus two biweekly postemergence applications to goosegrass and smooth crabgrass plants to simulate the first 1.5 mo of typical PGR programs used on golf courses. Two weeks after the final postemergence treatment, aboveground biomass and root biomass were recorded. Programmatic flurprimidol and paclobutrazol applications reduced smooth crabgrass aboveground biomass by 67% and 69%, respectively, and more than trinexapac ethyl or prohexadione-calcium. When averaged across application programs, flurprimidol and paclobutrazol reduced smooth crabgrass root biomass by 74% and goosegrass biomass by 73% to 80%. Field studies were established to further evaluate the influence of PGRs on smooth crabgrass coverage in creeping bentgrass turf. Treatments consisting of flurprimidol, trinexapac-ethyl, flurprimidol plus trinexapac-ethyl, paclobutrazol, and fenoxaprop-p were applied every 3 wk from April to August. Weed coverage data were collected throughout the growing season, and final smooth crabgrass control data were collected at the end of the season. In general, flurprimidol-containing treatments more effectively reduced smooth crabgrass coverage throughout the growing season than trinexapac ethyl. After the studies, regimens that contained flurprimidol controlled smooth crabgrass by 68% to 73%, greater than any other PGR program evaluated. Results from these studies indicate that flurprimidol may be used to effectively control smooth crabgrass or goosegrass in creeping bentgrass turf. These are the first reported data regarding the use of flurprimidol for smooth crabgrass or goosegrass control in turf.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
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
© The Author(s), 2024. Published by Cambridge University Press on behalf of Weed Science Society of America

Introduction

Goosegrass and smooth crabgrass are problematic weeds in creeping bentgrass putting greens due to a lack of selective herbicide options. Currently, only five preemergence herbicides are labeled for control of goosegrass and smooth crabgrass in creeping bentgrass putting greens. These include bensulide, dithiopyr, siduron, methiozolin, and oxadiazon. Although bensulide is generally safe for creeping bentgrass turfgrass (Callahan and McDonald Reference Callahan and McDonald1992) and effectively controls smooth crabgrass (Bingham and Schmidt Reference Bingham and Schmidt1967), it marginally controls goosegrass (Johnson Reference Johnson1982). Oxadiazon is commonly used for goosegrass and smooth crabgrass control in creeping bentgrass putting greens when applied with bensulide. Potential for creeping bentgrass injury (Johnson Reference Johnson1987) and incidents of goosegrass resistance to oxadiazon (McElroy et al. Reference McElroy, Head, Whetje and Spak2017) have driven many turfgrass managers to seek alternative methods for goosegrass and smooth crabgrass control in creeping bentgrass putting greens. Although some studies indicate that dithiopyr can be safely applied to creeping bentgrass putting greens (Dernoeden et al. Reference Dernoeden, Christians, Krouse and Roe1993; Johnson Reference Johnson1994), it is rarely used by turfgrass managers due to restrictions on most product labels and the potential for stress-associated creeping bentgrass injury (Bhowmik and Bingham Reference Bhowmik and Bingham1990; Hart et al. Reference Hart, Lycan and Murphy2004). Brewer and Askew (Reference Brewer and Askew2021) found that siduron selectively controls smooth crabgrass when applied biweekly at 5.6 kg ai ha−1. However, siduron registration was not renewed during a recent review by the U.S. Environmental Protection Agency (US EPA 2018).

Methiozolin is a newly registered herbicide that is labeled for goosegrass and smooth crabgrass control in creeping bentgrass putting greens (Anonymous 2021). Creeping bentgrass putting green safety has been well documented with methiozolin (Askew Reference Askew2017; Askew and McNulty Reference Askew and McNulty2014; Hoisington et al. Reference Hoisington, Flessner, Schiavon, McElroy and Baird2014; McCullough et al. Reference McCullough, Gomez de Barreda and Jialin2013), and methiozolin selectively controls goosegrass and smooth crabgrass when applied frequently preemergence (Peppers et al. Reference Peppers, McElroy, Orlinski, Baird, Petelewicz, Joseph, Sierra-Augustinus, Schiavon and Askew2024). However, methiozolin may be cost prohibitive for some turfgrass managers. In addition to recent studies of methiozolin (Peppers et al. Reference Peppers, McElroy, Orlinski, Baird, Petelewicz, Joseph, Sierra-Augustinus, Schiavon and Askew2024), other herbicides such as fenoxaprop-p ethyl and topramezone have successfully controlled smooth crabgrass or goosegrass when applied frequently at low doses on creeping bentgrass putting greens (Brewer and Askew Reference Brewer and Askew2021). This frequent treatment schedule for low doses of selected herbicides is similar to how plant growth regulators (PGRs) are used on golf greens.

PGRs are regularly used to suppress turfgrass growth, increase turfgrass green color, enhance abiotic stress tolerance, increase turfgrass stand density, and reduce plant water usage (Baldwin et al. Reference Baldwin, Liu, McCarty, Luo and Toler2009; Beam and Askew Reference Beam and Askew2005; King et al. Reference King, Blundell, Evans, Mander and Wood1997; McCarty et al. Reference McCarty, Willis, Toler and Whitwell2011; McCullough et al. Reference McCullough, Liu and McCarty2005). Paclobutrazol, ethephon, and flurprimidol are also regularly used to selectively suppress annual bluegrass (Poa annua L.) (Askew Reference Askew2017; Peppers et al. Reference Peppers, Brewer and Askew2021; Reicher et al. Reference Reicher, Sousek, Patton, Van Dyke, Kreuser, Inguagiato, Miele, Brewer, Askew, Hathaway, Nikolai, Kowalewski and McDonald2020) or to control it (Johnson and Murphy Reference Johnson and Murphy1995; Reicher et al. Reference Reicher, Sousek, Patton, Weisenberger, Hathaway and Calhoun2015) in turf. These PGRs reduce the competitive advantage of annual bluegrass relative to creeping bentgrass (Johnson and Murphy Reference Johnson and Murphy1996). Lowe and Whitwell (Reference Lowe and Whitwell1999) evaluated goosegrass and large crabgrass (Digitaria sanguinalis L.) suppression via several PGRs applied postemergence, including trinexapac-ethyl, flurprimidol and paclobutrazol. No PGR evaluated reduced goosegrass or large crabgrass height greater than bermudagrass in this study. However, no peer-reviewed literature has evaluated these PGRs applied preemergence on goosegrass or smooth crabgrass.

In a long-term preliminary PGR study, Dernoeden (Reference Dernoeden1982) observed that plots of Kentucky bluegrass (Poa pratensis L.) turfgrass treated with two yearly applications of flurprimidol had significantly less smooth crabgrass coverage than nontreated and mefluidide-treated plots. Although this observation was not further investigated by Dernoeden in any subsequent peer-reviewed literature, these results suggest that flurprimidol may have herbicidal activity on smooth crabgrass. In a preliminary study, Sawyer et al. (Reference Sawyer, Wakefield and Jagschitz1983) observed a reduction in crabgrass (Digitaria spp.) establishment following applications of paclobutrazol and flurprimidol. No peer-reviewed literature was subsequently published further investigating the potential for smooth crabgrass control in turfgrass with paclobutrazol or flurprimidol. However, many subsequent studies have demonstrated the preemergence efficacy of paclobutrazol and flurprimidol on plant germination. Several researchers have found that flurprimidol reduces creeping bentgrass and annual bluegrass germination when applied preemergence (Gaussoin and Branham Reference Gaussoin and Branham1987; Haley and Fermanian Reference Haley and Fermanian1989). Paclobutrazol inhibits the seed germination of many species of vegetables and other horticultural crops (Koukourikou-Petridou Reference Koukourikou-Petridou1996; Mage and Powell Reference Mage and Powell1990; Pressman and Shaked Reference Pressman and Shaked1988).

Based on existing literature, we hypothesized that programmatic applications of flurprimidol or paclobutrazol would reduce smooth crabgrass and goosegrass coverage on creeping bentgrass putting greens, likely through residual effects on germinating seedlings or postemergence suppression of weedy grasses to favor improved turfgrass density. Therefore, studies were designed to evaluate four PGRs commonly used in creeping bentgrass putting greens for their effects on goosegrass and smooth crabgrass growth when applied prior to weed emergence and when multiple treatments are extended through the summer season.

Materials and Methods

Goosegrass and Smooth Crabgrass Greenhouse Response to Preemergence-Applied PGRs

Four greenhouse studies were conducted between winter 2021 and spring 2022 to evaluate smooth crabgrass and goosegrass foliar growth and root development in response to four PGRs applied either once preemergence or thrice biweekly. Two studies evaluated smooth crabgrass, whereas the other two evaluated goosegrass. All studies were repeated in time and space. Trials were arranged as randomized complete block designs with six replications and nine treatments that included an embedded four-by-two factorial arrangement with four levels of PGR treatment and two levels of application program compared to a nontreated control. The four levels of PGR treatment were flurprimidol (Cutless® MEC; SePro Corp, Carmel IN) applied at 280 g ai ha−1, paclobutrazol (Trimmit® 2SC; Syngenta Crop Protection LLC, Greensboro, NC) applied at 280 g ai ha−1, trinexapac-ethyl (PrimoMaxx®; Syngenta) applied at 53 g ai ha−1, and prohexadione-calcium (Anuew; Nufarm Americas Inc., Morrisville, NC) applied at 154 g ai ha−1. The two levels of the application program included a single application made 1 h following seeding and a single application made 1 h after seeding followed by two additional biweekly applications to simulate a PGR reapplication schedule typically employed by golf course superintendents.

Approximately 50 goosegrass seeds and approximately 100 smooth crabgrass seeds were seeded into 4.4- by 7.6- by 12.7-cm pots containing a 2:1 ratio of sand to native soil mixture. The native soil admixture was a Groseclose-Urban land complex loam (clayey, mixed, mesic Typic Hapludults), pH 6.0, with 3.1% organic matter. All plants were fertilized with approximately 25 kg N ha−1 approximately 1 wk after germination to maintain proper plant growth. Irrigation was supplied twice daily to prevent plant wilt. Supplemental lighting of 750 µmol s−1 photosynthetically active radiation via sodium halide lights was set to a 14-h daylength throughout the studies. Greenhouse day/night temperatures were maintained at 29/24 C. All treatments were applied with a CO2-pressurized backpack sprayer calibrated to deliver 374 L ha−1 at 331 kPa via TeeJet TTI11004 nozzles (Spraying Systems Co., Wheaton, IL). Following application, all pots were allowed to dry for 2 h before applying approximately 3 mm of overhead irrigation. Two weeks following the final application, aboveground biomass and root biomass were measured. Aboveground biomass was collected and dried at 50 C for 72 h prior to weighing. Root biomass was removed from each pot, washed clean of all debris, then dried at 50 C for 72 h, and weighed. The dried roots were then ashed in a muffle furnace at 500 C for approximately 8 h. The weight of the resulting matter was then weighed and subtracted from the measured root dry weight. Data were subjected to ANOVA with SAS software (v. 9.4; SAS Institute, Cary, NC) with sums of squares partitioned to reflect the four by two factorial treatment design and trial effects as previously described. Appropriate means were separated with Fisher’s protected LSD test at α = 0.05.

Field Evaluation of Smooth Crabgrass and Creeping Bentgrass as Affected by PGRs

Three field studies were conducted between 2022 and 2023 in Blacksburg, VA (37.22°N, 80.41°W), to evaluate smooth crabgrass control in creeping bentgrass using PGRs. Two trials were conducted at the Virginia Tech Turfgrass Research Center (TRC) and one at the Glade Road Research Facility (GRRF). The two trials at the TRC were conducted on an ‘L93’ creeping bentgrass putting green maintained at 3.2 mm in 2022 (TRC1) and 2023 (TRC2). The trial conducted at GRRF was conducted in 2023 on an L93 creeping bentgrass fairway maintained at 12.7 mm. All trials were arranged as randomized complete block designs with six treatments and four replications. The treatments evaluated were flurprimidol (140 g ai ha−1, Cutless MEC®; SePro Corporation, Rocky Mount, NC), trinexapac-ethyl (52.6 g ai ha−1, Primo Maxx®; Syngenta Crop Protection LLC), flurprimidol plus trinexapac-ethyl (Legacy®; SePro Corporation), paclobutrazol (175 g ai ha−1, Trimmit 2SC®; Syngenta Crop Protection LLC), fenoxaprop-p (17.5 g ai ha−1, Acclaim Extra®; Bayer Environmental Science), and a nontreated control plot. Flurprimidol and paclobutrazol application rates were less than the rates used in the greenhouse study to reduce turfgrass injury potential throughout the growing season. Herbicides were applied via CO2-pressurized sprayer calibrated to deliver 375 L ha−1 at 330 kPa. All treatments were applied every 3 wk, beginning prior to weed emergence (approximately April 15), throughout the growing season, for seven total applications per season. All treated plots received approximately 4 mm of irrigation approximately 2 h following application to wash flurprimidol and paclobutrazol treatments to the root system while also allowing for foliar absorption of trinexapac-ethyl and fenoxaprop-p. Smooth crabgrass coverage and creeping bentgrass injury were visually evaluated throughout the growing season as a percentage in which 0% equals no weed presence or turfgrass injury and 100% equals complete weed coverage or complete turfgrass death. At the conclusion of the studies (approximately August 30), smooth crabgrass coverage was assessed via line-intersect grids with 196 assessments per plot. Final assessments of weed control were extrapolated from the line-intersect counts by comparing weed coverage in the nontreated control in each replication versus the coverage in each treated plot. To control for variance structure in repeated measures over time, smooth crabgrass coverage data were transformed to the daily area under the progress curve (AUPC) (Askew et al. Reference Askew, Goatley, Askew, Hensler and McKissack2013). The area under the resulting curves was calculated using Equation 1:

([1]) $${\rm{AUPC}} = {\sum\nolimits^{ni}}^{ - 1}\left\{ {\left[ {\left( {{y_i} + {y_i}_{ + 1}} \right)/2} \right]*\left[ {{t_i}_{ + 1} - ti} \right]} \right\}$$

where y i is response variable y at the ith observation, t i is days after initial application at the ith observation, and n is the number of observations. The resulting AUPC was then converted to AUPC d−1 by dividing AUPC by the total number of days spanned by assessments. Similarly, creeping bentgrass injury data were expressed as the number of days over an injury threshold of 20% (DOT20). These injury DOT20 values were calculated assuming linear trends in changes to creeping bentgrass injury between assessment dates. All data were subjected to ANOVA with SAS software (v. 9.4) to test for significance between trial locations and treatments with appropriate means separated using Fisher’s protected LSD at α = 0.05. The nontreated control plot data were excluded from the analysis for the end-of-season smooth crabgrass control data.

Results and Discussion

Goosegrass and Smooth Crabgrass Response to PRE-Applied PGRs in a Controlled Environment

The trial-by-treatment interaction on smooth crabgrass aboveground biomass was insignificant (P = 0.654), therefore, aboveground biomass data were pooled over the two greenhouse trials. The PGR main effect, the application program main effects, and PGR by application program interaction, were significant (P = <0.0001, 0.025, and 0.036, respectively). Single preemergence applications of flurprimidol, paclobutrazol, and trinexapac-ethyl reduced smooth crabgrass aboveground biomass by 34%, 37%, and 17% respectively, relative to the nontreated control (Table 1). Single preemergence prohexadione-calcium applications did not reduce smooth crabgrass aboveground biomass compared with the other PGR treatments. Turfgrass response to prohexadione-calcium varies depending on species when the product is applied to actively growing foliage (Beam and Askew Reference Beam and Askew2005), but plant response to preemergence treatments has not been reported. For all PGR treatments except trinexapac-ethyl, two additional biweekly applications reduced smooth crabgrass biomass compared to single preemergence applications. Three biweekly applications of flurprimidol and paclobutrazol reduced smooth crabgrass aboveground biomass by 67% and 69%, respectively, relative to the nontreated control, and more than trinexapac-ethyl and prohexadione-calcium. Three biweekly applications of trinexapac-ethyl and prohexadione-calcium reduced smooth crabgrass aboveground biomass compared to the nontreated control similarly (21% and 33%, respectively). Trinexapac-ethyl was the only PGR for which additional applications did not further decrease smooth crabgrass aboveground biomass.

Table 1. Influence of plant growth regulator and either a single PRE application or three biweekly applications (PRE + POST) on smooth crabgrass and goosegrass aboveground and root biomass percent reduction relative to the nontreated control in a greenhouse study. ac

a Abbreviations: PGR, plant growth regulator; POST, postemergence; PRE, preemergence.

b Different letters following means indicate significant differences between means within a given column. A negative value indicates an increase relative to the nontreated, whereas positive values indicate a decrease relative to the non-treated.

c Letters followed by asterisks (**) indicate significant differences between application programs within a given PGR treatment.

d Flurprimidol, paclobutrazol, prohexadione-calcium, and trinexapac-ethyl treatments were applied at 280, 280, 154, and 53 g ai ha−1, respectively. Approximately 3 mm of irrigation was applied 2 h after application to ensure root uptake of flurprimidol and paclobutrazol.

The main effect of PGR was significant for smooth crabgrass root biomass (P = 0.0002), and this was not influenced by the interacting effects of the trial (P = 0.185) or application program (P = 0.381). Multiple PGR applications did not reduce root biomass compared to single preemergence applications. This lack of application program effect was expected from trinexapac ethyl and prohexadione-calcium since they had minimal impact on foliar biomass and did not reduce root biomass more than 15% (Table 1). The lack of a differential effect on root biomass from flurprimidol and paclobutrazol was surprising because these products applied sequentially reduced foliar biomass to approximately half that of plants treated only once (Table 1). Apparently, flurprimidol and paclobutrazol are highly effective at reducing root biomass regardless of the number of treatments, as they reduced smooth crabgrass root biomass by 74% on average compared to the nontreated control (Table 1).

The effect of the trial on goosegrass aboveground biomass was also insignificant (P = 0.681). Therefore, data are pooled over trials. The main effects of PGR and application program on goosegrass aboveground biomass were significant (P = 0.008 and P = 0.029, respectively), with no significant interaction (P = 0.191). Like smooth crabgrass, trinexapac-ethyl and prohexadione-calcium had limited effect on goosegrass growth regardless of application program. When averaged over both application programs, flurprimidol and paclobutrazol reduced goosegrass aboveground biomass by 66% and 59%, respectively, relative to the nontreated control (Table 1). Trinexapac-ethyl and prohexadione-calcium reduced goosegrass aboveground biomass by 24% and 19%, respectively, relative to the nontreated control. Single and sequential PGR applications reduced goosegrass aboveground biomass by 28% and 56%, respectively, relative to the nontreated control, and were significantly different (data not shown).

The main effect of PGR was the only significant effect on goosegrass root biomass reduction (P = 0.029). When averaged across application programs, flurprimidol and paclobutrazol reduced goosegrass root biomass by 80% and 73%, respectively (Table 1). Conversely, trinexapac-ethyl and prohexadione-calcium only reduced goosegrass root biomass by 27% and 24%, respectively.

Results from this study indicate that flurprimidol and paclobutrazol reduce smooth crabgrass and goosegrass aboveground and root biomass more than trinexapac-ethyl and prohexadione-calcium. Previous research indicates that trinexapac-ethyl will not affect or increase the rooting of other grass species (McCarty et al. Reference McCarty, Willis, Toler and Whitwell2011; McCullough et al. Reference McCullough, Liu and McCarty2005). Prohexadione-calcium is similar to trinexapac-ethyl in that both are late-stage gibberellin inhibitors in the same chemical family (Beam and Askew Reference Beam and Askew2005; Nakayama et al. Reference Nakayama, Kobayashi, Kamiya and Sakurai1992). Previous research also indicates limited influence of trinexapac-ethyl and prohexadione-calcium specifically on goosegrass and crabgrass species. Henry et al. (Reference Henry, Moore and Tucker2020) observed low growth regulation (14% to 30%) of goosegrass and moderate regulation (40% to 49%) of large crabgrass (Digitaria sanguinalis L.) with trinexapac-ethyl and prohexadione-calcium. Additionally, preliminary research indicates that trinexapac-ethyl can even increase goosegrass growth in creeping bentgrass turfgrass systems (Diehl and Elmore Reference Diehl and Elmore2024). Conversely, paclobutrazol and flurprimidol can decrease the root biomass of creeping bentgrass (Fagerness and Yelverton Reference Fagerness and Yelverton2001; Hanson and Branham Reference Hanson and Branham1987). Although flurprimidol and paclobutrazol reduced weed root biomass by a significant amount in this study, the reduction was not comparable to that of typical preemergence herbicides such as dinitroanilines (Bhowmik and Bingham Reference Bhowmik and Bingham1990; Johnson Reference Johnson1996). In these studies, however, flurprimidol and paclobutrazol reduced smooth crabgrass and goosegrass root biomass more than previously reported creeping bentgrass root reduction from flurprimidol and paclobutrazol (approximately 20% reduction; Fagerness and Yelverton Reference Fagerness and Yelverton2001). Additionally, flurprimidol and paclobutrazol reduced weed aboveground biomass by approximately 65%, whereas paclobutrazol reduced creeping bentgrass aboveground growth by approximately 50% in a previous study by Kreuser et al. (Reference Kreuser, Obear, Michael and Soldat2018). Results from our studies corroborate the limited goosegrass and smooth crabgrass growth regulation observed following trinexapac ethyl or prohexadione-calcium treatment in previous literature, but this study is the first to present data comparing root and foliar growth of goosegrass and smooth crabgrass in response to flurprimidol and paclobutrazol. These data indicated that flurprimidol or paclobutrazol may reduce the competitiveness of smooth crabgrass and goosegrass in creeping bentgrass, which suggested that further field evaluations were warranted.

Field Evaluation of Smooth Crabgrass and Creeping Bentgrass as Affected by PGRs

The trial-by-treatment interaction was significant for smooth crabgrass AUPC d−1 (P < 0.0001); therefore, the three trials are presented separately. An increase in smooth crabgrass cover at TRC1 likely reduced treatment performance and contributed to the trial interaction. For example, trinexapac ethyl smooth crabgrass AUPC d−1 was equivalent to nontreated turfgrass at TRC1 but differed at the other two locations. Flurprimidol + trinexapac also performed inconsistently across locations because it decreased smooth crabgrass AUPC d−1 compared to trinexapac ethyl at TRC1 and GRRF, but not at TRC2 (Table 2). TRC2 received more frequent applications of preventative fungicides and was maintained with approximately 60% greater nitrogen fertility (data not shown). Trinexapac-ethyl is commonly applied to improve creeping bentgrass quality (Fagerness et al. Reference Fagerness, Yelverton, Isgrigg and Cooper2002; King et al. Reference King, Blundell, Evans, Mander and Wood1997; Kreuser and Soldat Reference Kreuser and Soldat2011) and may have increased the ability of creeping bentgrass to compete against smooth crabgrass at TRC2. Trinexapac-ethyl suppressed smooth crabgrass early in the growing season similar to other treatments at this location resulting in lower AUPC d−1 at TRC2 relative to other trial locations. Despite these differences, the mean rank at TRC2 and GRRF were similar for all treatments and both fenoxaprop-p and flurprimidol consistently yielded the lowest smooth crabgrass AUPC d−1 at all sites.

Table 2. Influence of treatment on smooth crabgrass coverage area under the progress curve per day and end-of-season control. a, b

a Abbreviations: AUPCD, area under the progress curve d−1; GRRF, Glade Road Research Facility; TRC1 and TRC2, Virginia Tech Turfgrass Research Center trial 1 and trial 2, respectively.

b Letters following means denote significant differences between means within a given column.

c AUPCD was calculated by assuming linear changes in smooth crabgrass coverage between rating assessments.

d Trials at TRC1 and TRC2 were conducted on ‘L93’ creeping bentgrass putting greens maintained at 3.2 mm. The trial at GRRF was conducted on an L93 creeping bentgrass fairway maintained at 12.7 mm.

e End-of-season smooth crabgrass control was derived via line-intersect counts taken at the conclusion of the trial (approximately August 30) and compared with that of the nontreated within a given replication.

f Approximately 4 mm of irrigation was applied approximately 2 h following application to allow for root uptake of flurprimidol and paclobutrazol according to label recommendations.

It should be noted that all of these sites had smooth crabgrass infestation levels that resulted in nearly complete late-season smooth crabgrass coverage (data not shown). Evidence of high weed pressure lies in the smooth crabgrass coverage AUPC d−1, which was 44% to 59% depending on the site. Considering that the season starts with no smooth crabgrass and considerable time is needed for smooth crabgrass population expansion, these AUPC d−1 values would necessitate more than 70% late-season smooth crabgrass coverage at all sites. Although smooth crabgrass AUPC d−1 following paclobutrazol treatment was always numerically twice that of flurprimidol or fenoxaprop-p, paclobutrazol plots had statistically equivalent AUPC d−1 compared to flurprimidol and fenoxaprop-p at two of the three locations (Table 2).

The trial-by-treatment interaction for end-of-season smooth crabgrass control was insignificant (P = 0.193), whereas the treatment main effect was significant (P < 0.0001); therefore, all end-of-season smooth crabgrass control data were pooled over sites. Fenoxaprop-p controlled smooth crabgrass by 95%, greater than all other treatments (Table 2). However, fenoxaprop-p was the only treatment that significantly increased creeping bentgrass injury DOT20 compared to the nontreated plots (17 d; data not shown). Averaged across all site-years, flurprimidol alone and in conjunction with trinexapac-ethyl controlled smooth crabgrass by 76% and 68%, respectively, more than all other PGR treatments. Although greenhouse studies indicated that paclobutrazol should suppress smooth crabgrass similarly to flurprimidol, late-season smooth crabgrass control by paclobutrazol was 46%, which was less than that of flurprimidol and more that of trinexapac-ethyl (18%). The differential response of late-season smooth crabgrass to paclobutrazol and flurprimidol appears to conflict with season-long AUPC data in which both PGRs collectively controlled smooth crabgrass equivalently. Responses following the two PGR treatments diverged only at the end of the season. Potentially greater creeping bentgrass suppression with paclobutrazol during periods of heat stress may have limited late-season competition between creeping bentgrass and smooth crabgrass. Although paclobutrazol has been reported to injure creeping bentgrass during summer heat (Baldwin and Brede Reference Baldwin and Brede2011), visible evidence of creeping bentgrass injury was not apparent in the current study.

These results indicate that flurprimidol-containing treatments will more effectively suppress smooth crabgrass throughout the growing season in creeping bentgrass than other PGR treatments, particularly trinexapac-ethyl. These results are consistent with previous literature in which flurprimidol effectively suppressed grass species when applied preemergence (Gaussoin and Branham Reference Gaussoin and Branham1987; Haley and Fermanian Reference Haley and Fermanian1989). Although flurprimidol and paclobutrazol share a similar mode of action (Ervin and Zhang Reference Ervin, Zhang and Pessarakli2008), peer-reviewed literature evaluating paclobutrazol on grass germination is lacking. Several published studies have detailed germination inhibition via paclobutrazol but are limited to broadleaf plant species (Koukourikou-Petridou Reference Koukourikou-Petridou1996; Mage and Powell Reference Mage and Powell1990; Pasian and Bennett Reference Pasian and Bennett2001; Pressman and Shaked Reference Pressman and Shaked1988). Conversely, flurprimidol reduces grass species germination (Gaussoin and Branham Reference Gaussoin and Branham1987; Haley and Fermanian Reference Haley and Fermanian1989). It is possible that the difference in smooth crabgrass control between paclobutrazol and flurprimidol is a difference in selectivity. However, paclobutrazol and flurprimidol similarly affected smooth crabgrass in the greenhouse. It is more likely that the difference in smooth crabgrass control with paclobutrazol and flurprimidol was due to differential late-season creeping bentgrass suppression between the two growth regulators.

Practical Implications

Results from these studies indicate programmatic flurprimidol use can significantly reduce smooth crabgrass and goosegrass invasion into creeping bentgrass turf. In the U.S. transition zone, trinexapac-ethyl is commonly used on creeping bentgrass turfgrass in the summer months to increase putting green speed, color, and root mass (Fagerness et al. Reference Fagerness, Yelverton, Isgrigg and Cooper2002; King et al. Reference King, Blundell, Evans, Mander and Wood1997; Kreuser and Soldat Reference Kreuser and Soldat2011). Conversely, flurprimidol and paclobutrazol are often avoided due to perceived injury risks to creeping bentgrass in warmer, transition-zone summers as was observed by Baldwin and Brede (Reference Baldwin and Brede2011). However, neither paclobutrazol nor flurprimidol unacceptably injured creeping bentgrass in this research, which is consistent with previous literature (Koski Reference Koski1997; Petelewicz Reference Petelewicz, Orlinski and Baird2021; Reicher et al. Reference Reicher, Sousek, Patton, Weisenberger, Hathaway and Calhoun2015). Many turfgrass managers include early-gibberellin-inhibiting PGRs with trinexapac-ethyl applications to prolong creeping bentgrass growth suppression while maintaining the physiological benefits associated with trinexapac-ethyl applications (Kreuser et al. Reference Kreuser, Obear, Michael and Soldat2018). Results from these studies indicate that flurprimidol and trinexapac-ethyl applied in conjunction controls smooth crabgrass as effectively as flurprimidol applied alone. Likewise, paclobutrazol increased smooth crabgrass control more than trinexapac ethyl, but not as much as programs that contain flurprimidol. Although goosegrass was not evaluated in the field studies, it responded similarly to that of smooth crabgrass in the greenhouse studies. It can be inferred that flurprimidol may control goosegrass similarly to smooth crabgrass. Preliminary observations by McElroy et al. (Reference McElroy, Boyd, Peppers and Brown2018) indicate that flurprimidol can effectively reduce goosegrass coverage within creeping bentgrass putting greens. These are the first published data regarding using flurprimidol or paclobutrazol for selective control of smooth crabgrass or goosegrass in creeping bentgrass turf.

Acknowledgments

We thank Mr. John Hinson for maintaining research plots in Blacksburg, VA.

Funding

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

Competing interests

The authors declare they have no competing interests.

Footnotes

Associate Editor: Prashant Jha, Louisiana State University

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Figure 0

Table 1. Influence of plant growth regulator and either a single PRE application or three biweekly applications (PRE + POST) on smooth crabgrass and goosegrass aboveground and root biomass percent reduction relative to the nontreated control in a greenhouse study.a–c

Figure 1

Table 2. Influence of treatment on smooth crabgrass coverage area under the progress curve per day and end-of-season control.a,b