Persistence of Methiozolin Applied to Cynodon dactylon × transvaalensis Putting Greens

Studies were conducted between 2021 and 2022 in Midlothian, VA, at the Independence Golf Club (37.54°N, 77.69°W) to evaluate methiozolin soil persistence when applied to sand-based C. dactylon ×transvaalensis putting greens. Three biweekly applications of methiozolin (500 g ai ha⁻¹, PoaCure, Moghu Research Center) were carried out according to label recommendations for spring P. annua control on 12 putting greens that acted as replications. Each putting green had a sand-based root zone that meets the U.S. Golf Association (USGA) specifications for root zone construction (USGA 2018). Soil pH was 6.5 ± 0.2 and soil organic matter was 1.3 ± 0.4% (Table 1). Putting greens were maintained at 4 mm, and clippings were removed with mowing. Nine replications were conducted in 2021 and three replications were conducted in 2022.

Table 1.

Putting green description of cultivar, age at the time of study initiation, soil pH, and soil organic matter for each putting green evaluated for methiozolin dissipation

^a Application dates in 2021 were February 24, March 10, and March 24; and in 2022, March 3, 17, and 30.

^b Putting green soils were built to U.S. Golf Association specifications on all putting greens.

^c Soil organic matter was measured via loss on ignition from the top 6 cm of soil excluding the verdure and is presented as a percentage of soil dry weight.

Applications were made to a single 1.8 by 2.4 m plot per replication via a four-nozzle spray boom equipped with TTI 11006 spray tips (TeeJet Technologies, Springfield, IL, 62703, USA), operated at 358 kPa to deliver 374 L ha⁻¹. Applications were made on February 24, March 10, and March 24 in 2021, and March 3, March 17, and March 30 in 2022. Following each application, approximately 6.4 mm of irrigation was applied, according to label recommendations, to wash methiozolin from the foliage. Eight 2.5-cm-diameter soil cores per replicate putting green were collected at each sampling date at each of four random locations distributed across the plot. To prevent error associated with spray pattern overlap, four transects that corresponded to a line directly under the center of each spray nozzle were referenced in each plot. These four transects were parsed into nine positions spaced 20 cm apart along the plot length. At each of the nine assessment dates, a unique and random position was chosen from each of the four transects and two adjacent soil cores were collected. These eight soil cores were divided into two sampling depths that included verdure, thatch layer, and soil above 2 cm below the thatch layer and the soil located from 2 to 8 cm below the thatch layer, yielding two composite soil samples for each replicate putting green at each assessment date.

Soil cores were extracted immediately following trial initiation, immediately following the second spring application, and immediately following the final spring application in order to evaluate the rate of methiozolin accumulation over the course of the spring applications. Cores were then collected at 2, 4, 6, 8, 10, and 12 wk after the final spring application in order to evaluate the dissipation of methiozolin over the course of the summer. Immediately following soil core extraction, samples were stored with ice and transported to Blacksburg, VA (37.22°N, 80.41°W), where they were placed in a freezer and maintained at approximately −20 C until the extraction process began. Previous research demonstrated that methiozolin loss under these conditions after 18 mo was negligible (SJ Koo, personal communication).

In preparation for methiozolin extraction, soil samples were flash frozen with liquid nitrogen, then homogenized using a mortar and pestle. Large particles were removed by passing homogenized soil samples through a 2-mm sieve. A random sample of approximately 10 g of soil from each homogenized soil preparation was collected, weighed, and then placed in an air dryer at 60 C for 72 h until completely dry. Following the drying process, the soil was weighed, and the resulting loss in weight was used to extrapolate gravimetric water content of each sample.

Methiozolin extraction from the soil was conducted using the following methodology: Approximately 2 g of soil was weighed, placed into test tubes, and then homogenized. Ten milliliters of an 80:20 acetonitrile:high-performance liquid chromatography (HPLC) water mixture was added to the soil, homogenized, and then shaken for 30 min using a wrist-action shaker. The soil-containing test tube was then centrifuged for 10 min at 3,000 rpm. Approximately 6 ml of supernatant was transferred to separate test tubes using a 0.45-µm polytetrafluoroethylene (PTFE) syringe filter. The sample was then diluted by adding 990 µl of 50:50 acetonitrile:HPLC water solution to 10 µl of supernatant. One milliliter of the diluted sample was utilized for methiozolin concentration analysis. Methiozolin content was analyzed from the soil extract using HPLC (1290 Infinity, Agilent Technologies, Santa Clara, CA, USA) with a tandem mass spectrometer (6490-triple quadrupole, Agilent Technologies) (LC/MS/MS). The limit of quantitation (LOQ) was 0.025 ppm (on a wet weight basis) and the limit of detection (LOD) was 0.05 ppb (on a soil dry weight basis).

Data included C. dactylon ×transvaalensis percent visible green coverage and methiozolin concentration over time and were subjected to ANOVA using Proc Mixed SAS v. 9.4 (SAS Institute, Cary, NC, USA) with sums of squares partitioned to account for the effects of sampling time, year, sampling time by year, and replicate nested within year. Data were combined over year if the year by time interaction was insignificant (P > 0.05). If sampling time or any interaction with sampling time was significant (P < 0.05), then data were subjected to regression analysis to explain trends in the repeated measure over time. Cynodon dactylon × transvaalensis percent visible green coverage was modeled via a three-parameter Gompertz model using Equation 1:

([1]) $$y = a{e^{ - b{e^{ - kT}}}}$$

in which y equals the percent C. dactylon ×transvaalensis green coverage, a equals the asymptote, b equals the displacement along the x axis, k equals the rate of C. dactylon ×transvaalensis green coverage increase, and T equals time in days.

Methiozolin soil concentrations for all soil cores collected following the final methiozolin application were converted to a percentage of the soil methiozolin concentration measured immediately after the final methiozolin application. These methiozolin concentrations were subjected to nonlinear regression using the exponential decay equation (Equation 2):

([2]) $${C_t} = {C_0}{\rm{*\;}}{e^{\left( { - k{\rm{*}}t} \right)}}$$

where C _t is the percent methiozolin concentration at sampling time t; C ₀ is the initial methiozolin concentration at t ₀, which was always equal to 100%; k is the estimated rate constant of methiozolin dissipation; and t is time in days. The k values were estimated via PROC NLIN in SAS v. 9.4. Time required, in days, for 50% and 90% dissipation of methiozolin following the final application (D₅₀ and D₉₀, respectively) was calculated using Equations 3 and 4, respectively:

([3]) $${{\rm{D}}_{50}} = \left( {{{\ln \left( 2 \right)} \over k}} \right)$$

([4]) $${{\rm{D}}_{90}} = \left( {{{\ln \left( {10} \right)} \over k}} \right)$$

where D₅₀ and D₉₀ are time in days for 50% and 90% methiozolin dissipation, respectively, ln is the natural log, and k is the aforementioned predicted rate constant parameter.

Methiozolin soil concentrations for soil cores collected immediately following the second and third applications were converted to a percentage of measured methiozolin immediately following the initial application. Methiozolin concentrations measured in 2021 were subjected to nonlinear regression via the quadratic function with Equation 5:

([5]) $${C_t} = \left( {a*{t^2}} \right) + \left( {b*t} \right) + c$$

where C _t is the percent methiozolin concentration at sampling time t, a is an estimated parameter that determines the concavity of the curve, b is an estimated parameter that determines the slope and position of the curve, and c is the y intercept when t is 0. As methiozolin concentrations were calculated as a percent of methiozolin concentration following the initial application, y is set to 100. Due to variability between years in rate of accumulation, methiozolin concentrations measured in 2022 were subjected to linear regression using Equation 6:

([6]) $$y = mx + b$$

where y is the percent methiozolin concentration at sampling time x, m is the slope, and b is the y intercept. To compare methiozolin soil concentration to application rates utilized in previous research, methiozolin concentrations (in ppm) were converted (to g ai ha⁻¹) using the weight and area of each sample in Equation 7.

([7]) $${W_m} = \left[ {{{\left( {{{{\rm{ppm}}*{W_{\rm{s}}}} \over {{{10}^6}}}} \right)} \over {{A_{\rm{s}}}*{{10}^8}}}} \right]$$

where W _m is the weight of methiozolin (in g ai ha⁻¹), ppm is methiozolin concentration (in µg), W _s is the weight of the sample (in g), and A _s is the area of the sample (in cm²).

Dissipation of Field-applied Methiozolin as Affected by Turfgrass Coverage

A study was conducted from 2014 to 2015 in Frenchtown, NJ (40.54°N, 74.99°W) to evaluate methiozolin dissipation as influenced by the presence or absence of turfgrass coverage. This study was conducted in compliance with Good Laboratory Practices set forth in Title 40, Part 160 of the U.S. Code of Federal Regulations. The trial was arranged as a randomized complete block design with three treatments and three replications. In addition to a nontreated control, treatments included methiozolin applied at 897 g ai ha⁻¹ three times at biweekly intervals to P. pratensis turf and bare-ground soil. Turfgrass was mown at 8.9 cm throughout the duration of the study. The bare-ground plots were prepared via disk harrowing and were maintained vegetation-free using glyphosate (1.1 kg ai ha⁻¹) as needed throughout the duration of the study. Treated plots measured 6.1 by 16.8 m and were subdivided into 22 1.5 by 3 m subplots to ensure randomization in sample collection. The nontreated plots measured 3 by 9.1 m and were divided into six 1.5 by 3 m subplots. All plots were separated by approximately 30 m to ensure no cross-contamination via drift. The test site soil was a Penn silt loam (fine-loamy, mixed, superactive, mesic Ultic Hapludalfs) with 28%, 51%, and 21% sand, silt, and clay, respectively, with a pH of 6.7 and 2.7% soil organic matter.

Each application was uniformly applied to the treated turf and bare soil plots on May 6, May 20, and June 3, 2014. Applications were made with a tractor-mounted boom sprayer calibrated to deliver 374 L ha⁻¹ via TeeJet^® AI 11004 nozzles. The initial application to both treated plots was timed to approximate the typical start of herbicide applications in turf in the spring season in New Jersey. Following herbicide application, 2.5 mm of irrigation was administered according to label recommendations. Soil and grass samples in the treated plots were collected for analysis immediately following each application and at 1, 3, 7, 14, 28, 58, 92, 119, 165, and 294 d following the final application. In the nontreated control plot, soil samples were collected 8 d before trial initiation and 7 and 92 d following the final application for use as analytical controls and for procedural recovery samples. All samples were stored frozen until shipment via freezer truck to Ricerca Biosciences, where they were maintained frozen until the time of analysis. Samples of aboveground biomass, 0- to 7.6-cm depth of soil and 7.6- to 15-cm depth of soil were collected from all treated plots at each sampling timing. Aboveground biomass samples were only collected in turf-covered plots. The aboveground samples measured 77 cm², and the soil samples measured 7.6 cm in diameter. At each sampling timing in the treated turf plots, five grass samples were taken from each replication by removing all aboveground biomass within a 77-cm² area and combined to create a single sample per replication. Likewise, in each sampling timing in the treated turf and bare soil plots, five soil cores were taken from each replication and combined to give a single sample per replication.

The methiozolin from the grass and soil samples was extracted using the methods of Hwang et al. (Reference Hwang, Lim, Kim, Chang, Kim Kyun and Kim2013), filtered through 0.45-µm PTFE syringe filters, diluted (if required), and analyzed by LC/MS/MS (SIL-HTA, Shimadzu Scientific Instruments, Kyoto, Japan) equipped with a Phenomenex Luna column (2 mm by 150 mm by 5 μm; Torrance, CA, USA) for methiozolin. The LOQ was 0.01 ppm (on a wet weight basis). The LOD was 0.002 ppm (on a wet weight basis for grass and on a dry weight basis for soil).

Methiozolin dissipation rate and subsequent soil D₅₀ and D₉₀ values were calculated using Equations 2, 3, and 4, respectively. Methiozolin concentrations, in ppm were converted (to g ai ha⁻¹) using Equation 6. Methiozolin soil D₅₀ and D₉₀ were subjected to ANOVA using PROC GLM in SAS v. 9.4 with sums of squares partitioned to reflect replicate and treatment effects. Means were separated between turf-covered and bare-ground plots using Fisher’s protected LSD at α = 0.05.