Materials and methods

This work was approved by the Research Ethics Committee on Animal Use (CEUA) of the Universidade Tecnológica Federal do Paraná – Dois Vizinhos Campus (UTFPR-DV) under protocols 2017-009, 2018-023, and 2020-11.

The experiment was conducted during three non-consecutive years, 2017 (71 days), 2018 (105 days) and 2020 (92 days) in the Beef Cattle Sector (Ruminant Teaching and Research Center – NEPRU) of UTFPR-DV. It is located in the physiographic region called the Third Plateau of Paraná in the coordinates 25°44′ South and 53°04′ West, at 520 metres altitude. Climatological data were collected approximately 200 metres from the experimental area (Fig. 1). The soil is classified as dystroferric Red Nitosol with a clay texture, and the climate is Cfa, humid subtropical without a defined dry season, according to the Köppen classification (Alvares et al., Reference Alvares, Stape, Sentelhas, de Moraes Gonçalves and Sparovek2013).

Figure 1. Average temperature and the sum of rainfall from May to October of 2017, 2018 and 2020.

Source: GBIOMET (2022).

The experimental area has been managed in a crop-livestock integration system since 2017. It rotates between the cultivation of soybean (2018 and 2020) and corn (2017) during the summer. Black oat (A. strigosa) and annual ryegrass (L. multiflorum) are cultivated during the winter, which can be mixed with legumes, depending on the treatment: vetch (Vicia sativa L.) and white clover (Trifolium repens L.) in 2017, and arrowleaf clover was used in 2018 and 2020 (Trifolium vesiculosum Savi). In all years, the treatments were allocated in the same experimental paddocks.

The experimental design was completely randomized with three treatments and three replicates (paddocks) for each year of evaluation. The treatments were CONTROL: pasture of black oat and ryegrass; LEG: pasture of black oat and ryegrass mixed with legume; and SUP: pasture of black oat and ryegrass with energy supplementation of 10 g/kg of body weight (BW) based on dry matter. We used 54 Angus steers (18 each year) aged 22 ± 3 months with an average initial BW of 413.08 ± 4.56 kg. They were submitted to sanitary protocols for ectoparasites and endoparasites before the beginning of the experimental period.

The animals received 1 kg of supplement for every 100 kg BW daily at 12:00 pm. Ground corn was used as a supplement. Every 21 days, the animals were weighed to adjust the amount of supplement. The steers had access ad libitum to water and mineral salt. The experimental area had 7 hectares, subdivided into 10 paddocks of approximately 0.7 hectares. In nine of them, the treatments were applied, and one was used to keep the regulatory animals. Continuous grazing with a variable stocking rate was used according to the ‘put-and-take’ method (Mott and Lucas, Reference Mott and Lucas1952).

In all years, the implantation of the pasture occurred in May, varying the day according to climatic conditions. Grasses were sown in a row and legumes by broadcast. The sowing density was 55 kg/ha for black oat seeds, 25 kg/ha for ryegrass, 25 kg/ha for vetch (2017), 5 kg/ha for white clover (2017), and 10 kg/ha for arrowleaf clover (2018 and 2020). The inclusion of arrowleaf clover (2018 and 2020) was due to the low persistence of white clover after the animals' first grazing. Arrowleaf clover was more present throughout the pasture cycle. Fertilization at sowing was done with 250 kg/ha of formulated NPK 8-20-15 each year, and two applications of urea (45–%N), totalling 75 kg/ha of N per year.

Two animals (testers) were allocated to each paddock. The average daily weight gain (ADG kg/animal/day) was determined by weighing the steers on the first and last day of the experiment, fasting solids and liquids for 14 h. The body weight gain per hectare (BWG/ha) was calculated by multiplying the number of animals, days of the period, area of paddock, and the average ADG of the paddock (Kunrath et al., Reference Kunrath, Cadenazzi, Brambilla, Anghinoni, Moraes, Barro and Carvalho2014). For body weight gain per hectare per day (BWG/ha/day), BWG/ha was divided by the days of the total grazing period.

The beginning of the grazing period occurred when the forage mass (FM) reached approximately 1500 kg DM/ha. At the beginning of grazing, the animals underwent an adaptation period to husbandry and treatments for 15 days. Then, the evaluations of pasture and animals were carried out.

Forage mass (kg DM/ha) was estimated by the double sampling (Wilm et al., Reference Wilm, Costello and Klipple1944). The double sampling technique consists of visual observations (n-20 per paddock) of the pasture at different points in each paddock. Next, cuts (n-5) and measurements of the respective forage mass are made within a small square (0.5 m × 0.5 m). Calibration equations are then generated to estimate forage mass based on several visual observations of the pasture across the paddock. The average coefficients of determination of the resulting linear equations which estimate herbage mass based on visual observations of height sward were above 0.80. The evaluations were carried out every 21 days, and two pasture exclusion cages per paddock were placed to determine the daily herbage accumulation rate (HAR), which was calculated using the formula described by Campbell (Reference Campbell1966). The clipped sample was homogenized and divided. One part was used for DM determination in a forced-air oven at 55°C for 72 h. The other part was used for botanical (forage species in the pasture) and structural (stem and leaf) evaluation, but the latter did not apply to legumes.

We used grazing simulation samples for the pasture's chemical analysis (Table 1) (Moore and Sollenberger, Reference Moore, Sollenberger and Gomide1997). The animals were observed grazing, and after 15 h every 21 days, the samples of what the animals grazed were collected. This procedure was carried out for all paddocks in all periods and years.

Table 1. Chemical composition and digestibility of black oat and ryegrass pasture associated with animal supplementation or mixed with legumes by simulated grazing of finishing beef steers

The contents of total dry matter (TDM) were determined in an oven at 105°C for 16 h; ash and organic matter (ASH and OM) in a muffle furnace at 600°C for 4 h; crude protein (CP) by Kjeldahl's method (AOAC, Reference AOAC1997); ether extract (EE) was performed with petroleum ether in Ankom XT15 equipment for 1 h at 90°C; neutral detergent fibre (NDF) and acid detergent fibre (ADF) were determined by the filter bag methodology (Komarek et al., Reference Komarek, Manson and Thiex1996) using the NDF and FDA solutions proposed by Van Soest et al. (Reference Van Soest, Robertson and Lewis1991). The in vitro dry matter digestibility was determined using a Daisy II 200 incubator (Tecnal Technology) and presented as Wiseman (Reference Wiseman2018). The in vitro dry matter digestibility is the amount of dry matter ingested that is not excreted in faeces. It is calculated using the following formula (Wiseman, Reference Wiseman2018):

$$\displaystyle{{{\rm quantity\;}\;{\rm ingested}-{\rm quantity}\;{\rm voided}\;{\rm in}\;{\rm faeces}} \over {{\rm quantity}\;{\rm ingested}}}$$

The animals were slaughtered at the end of the pastures' production cycle in a slaughterhouse, 25 km from the experimental area, following the establishment's protocols. When they arrived at the slaughterhouse, they remained in lairage with water sprinkling to provide comfort and welfare. The steers were desensitized with a pneumatic gun and bled under humane slaughter rules.

The animals fasted and were weighed before being sent to the slaughterhouse. Subsequently, the carcass of the animals was weighed to determine the hot carcass yield. The carcass was weighed again after 12 h of chilling to determine cold carcass yield. The carcasses were cut in half. Following the methodology of Müller (Reference Müller1987), conformation data, carcass length, thigh thickness, leg length and perimeter and arm length were collected in the left half carcass.

A sample was collected between the 11th and 13th ribs to determine the loin eye area by measuring with tracing paper. In addition, the subcutaneous fat thickness was measured with a caliper at three different points. In the same sample, the carcass composition of bone, muscle and fat was determined according to the methodology of Hankins and Howe (Reference Hankins and Howe1946).

Data were analysed using the PROC MIXED procedure from SAS 9.2 program (SAS, 2000 SAS Institute Inc., Cary, NC, USA). The normality of the data was confirmed using the Shapiro–Wilk test, and the means were compared by the Tukey test at 5% significance when any difference was detected through ANOVA (P < 0.05). The statistical model was:

$${\rm Yijkl} = {\rm \mu} + {\rm ti} + {\rm aj} + {\rm t} \times {\rm Jia} + {\rm eaijk} + {\rm eijkl}$$

where Yijkl is the dependent variable, μ is the overall mean, ti is the effect of treatment i, aj is the effect of year j, t × aij is the interaction between the variables treatment and year ij, eaijk is the error for repeated measures in time ijk, and eijkl is the random error.