Lolium multiflorum seed collection and experimental procedures

Glyphosate-resistant L. multiflorum seeds (LOLMU-R) were collected from a biotype at the EMBRAPA Trigo company (28°16′S and 52°24′W) in the Passo Fundo city, Rio Grande do Sul state (RS), Brazil. The biotype was previously identified by dose-response curve studies after surviving chemical treatment in apple orchards (Vargas et al., Reference Vargas, Roman, Rizzardi and Silva2004). The recovery and germination experiments were conducted between June and December 2015, in two stages: recovery, carried out at the Center for Forage Research (30°21′S and 54°16′W) in São Gabriel (RS); and germination and resistance assessment at the Itaqui Campus of the Federal University of Pampa (RS) (29°12′S and 56°18′W).

Seed recovery

A completely randomized experiment with six replications was conducted to assess the recovery of LOLMU-R seeds that had passed through the digestive system of cattle. The treatments consisted of the following seed recovery times: 1, 2, 3, 4, 5 and 6 days after ingestion. Six Hereford steers with an average age of 2 years and an average weight of 350 kg were used, with each animal considered one replicate.

The animals were allocated in metabolism cages for 15 days for metabolic assays. Over the first 9 days, the animals were allowed to adapt to the environment and diet. The diet offered was composed of fresh forage from native grassland in sufficient quantity to meet the animal's nutritional requirement. Its botanical composition was mainly constituted by Axonopus affinis, Desmodiun incanum, Paspalum notatum and Paspalum plicatulum; and a chemical composition of 409 g/kg of dry matter, 71 g/kg of ash, 92 g/kg of crude protein and 604 g/kg of neutral detergent fibre. On day 9, LOLMU-R seeds were supplied via a flexible feeding tube manually inserted into the glottis, with 25 g of seeds/animal (12 112 seeds), estimated based on the 1000 seed weight of the LOLMU-R biotype.

The steers were fitted with polyvinyl chloride saddles and bags. The bags were changed three times a day to prevent the accumulation of faeces. The samples were homogenized every 24 h and a 10% subsample removed for analysis. These samples were washed under running water in a 1 mm mesh sieve to separate the LOLMU-R seeds. After recovery, the results were converted to 100% of faecal volume. The seeds were counted and pre-dried, then placed in plastic bags and stored at 6°C (±2°C) under 85% relative humidity (RH) until the germination tests.

Germination of the recovered seeds

A completely randomized design was used; with six replications (the seeds recovered from each animal were considered as different replications). The recovered LOLMU-R seeds were deposited onto Germtest® paper soaked in distilled water (equivalent to 2.5 times the weight of the paper), which was rolled up and placed into sealed plastic bags. The rolls were placed into a Biochemical Oxygen Demand (BOD) incubator at a constant temperature of 20°C, under a 12 h photoperiod and 70% RH.

For germination, only seeds recovered on the 2nd, 3rd and 4th days were considered, given the small number retrieved on the remaining assessment days. A germination test was also performed in the control treatment (no gut passage), using 50 seeds per repetition. At 14 days after sowing, the germination percentage (% in relation to the control) was determined considering normal seedlings with a root and shoot, in accordance with Regulations for Seed Analysis (Brasil, Reference Brasil2009).

Dose-response curve

In order to establish the resistance of the LOLMU-R seeds recovered after animal ingestion, a greenhouse experiment was carried out using a completely randomized design with four replications. After germination assessment, 100 seedlings were transplanted into 0.2 litres plastic pots (one plant per pot) filled with commercial substrate and maintained at field capacity. When the plants reached phenological stage 23 (BBCH, 1997), the maximum recommended dose (1080 g a.e/ha) of glyphosate [Roundup Original®, 360 grams of acid equivalent per litre – (g a.e/l)] was applied.

Twenty days after treatment, the tillers were transplanted to new experimental units (0.2 litres) – two tillers per pot, totalling 28 pots. The treatments were applied when the plants obtained from the tillers reached stage 23 (BBCH, 1997), with the following glyphosate doses: 0, 1080, 2160, 4320, 8640, 17 280 and 34 560 g a.e./ha. Application was performed using a CO₂ pressurized sprayer positioned 0.5 m from the target, equipped with a boom containing flat spray tip nozzles (XR 110.015) spaced 0.5 m apart, at a working pressure of 250 kPa. The average temperature, RH and wind speed during application were 24°C, 69% and 6.5 km/h, respectively.

At 28 days after application, population control (%) was visually assessed. The control was assessed using a percentage scale where a score of zero (0%) was established for no control and 100% for plant death (Burril et al., Reference Burril, Cardenas and Locatelli1976). The remaining plants were cut at ground level and dried in a forced-air oven (60°C) until constant weight, when shoot dry weight (SDW) was determined.

Statistical analysis

The data obtained were analysed using R software (R Core Team, 2021). The recovered seeds and dose-response curve data were fitted via the three or four-parameter logistic model (3 or 4PL) (Ritz et al., Reference Ritz, Baty, Streibig and Gerhard2015), using the drc package (Eqns (1) and (2), respectively).

(1)$$Y = {\rm \;}\displaystyle{d \over {1 + {\rm exp}\{ {b( {\log ( x ) -\log ( {{\rm D}50} ) } ) } \} }}\;$$

(2)$$Y = {\rm \;}c + \displaystyle{{d-c} \over {1 + {\rm exp}\{ {b( {\log ( x ) -\log ( {{\rm D}50} ) } ) } \} }}\;$$

where Y is the resulting response value for dependent variables, either number of recovered seeds, control or SDW; d is the upper limit, defined by the maximum response from the number of recovered seeds or from non-treated plants (control or SDW); c is the lower limit, determined by the response levels from a high dose of herbicide – if c = 0, then the four-parameter model (Eqn (2)) reduces to the three-parameter model (Eqn (1)), with the lower limit being zero; D₅₀ is the time or dose that causes 50% of recovery seed, control or SDW reduction; and b the slope of the curve at D₅₀ (Ritz et al., Reference Ritz, Baty, Streibig and Gerhard2015).

The regression model was submitted to lack of fit testing using the modelFit function and when not significant (P ≥ 0.05) indicates that the data are well described by the selected model. The parameters and their standard errors were estimated using the drm function, with P values (P ≤ 0.05) dictating whether the parameters were significant. D₅₀ was estimated using the ED function, with a 95% confidence interval. Data on SDW and control were converted into a percentage in relation to the control treatment.

Germination of the recovered seeds data was fitted via linear regression (Eqn (3)), using lm function (Kniss and Streibig, Reference Kniss and Streibig2019).

(3)$$Y = a + b \, {\rm \ast } \, x$$

where Y corresponds to germination (%); a is the intercept of regression line, the predicted value when x = 0; b is the slope of the regression line; x = days after ingestion.

The regression model was submitted to lack of fit testing, treating the independent variable as a factor variable and comparing with the fitted linear model using the ANOVA function, when not significant (P ≥ 0.05), regression analysis describes data appropriately. The lm function was used to analyse whether parameters were significant (P ≤ 0.05), to estimate the standard errors and to determine the adjusted r² (Kniss and Streibig, Reference Kniss and Streibig2019).