Legume inclusion or nitrogen fertilization on Aruana grass overseeded with temperate grasses: Performance, carcass characteristics, and fatty acid profile of the meat of beef steers

Schmitz, Gean Rodrigo; Paris, Wagner; Kuss, Fernando; Nörnberg, José Laerte; Costa, Olmar Antônio Denardin; Souza, Saimon de Souza e; Menezes, Luis Fernando Glasenapp de

doi:10.37496/rbz5220210051

ABSTRACT

The objective of our study was to evaluate the effect of the use of legume (Arachis pintoi) or nitrogen fertilization on animal performance, characteristics of carcass and meat, and fatty acids profile of crossbred steers on Megathyrsus maximus cv. Aruana pasture, overseeded with temperate grasses. The experimental design was completely randomized, with three treatments and three replicates. The experiment was carried out from June to October (127 d). The treatments were: Low-N: 100 kg of N/ha; Medium-N: 200 kg of N/ha; and Legume: Arachis pintoi + 100 kg of N/ha. The pasture with higher nitrogen fertilization (N200) showed a more significant forage mass yield. The mixed grass with legumes presented a higher concentration of saturated fatty acids and saturated:unsaturated ratio in the meat. However, the grass pastures resulted in a higher content of unsaturated fatty acids in the meat. The other pasture variables, and characteristics of carcass and meat were not influenced by the treatments. The increase in nitrogen fertilization, from 100 to 200 kg/ha, and Arachis pintoi mixed with Aruana grass pasture overseeded with black oat and ryegrass does not affect the daily weight gain and the carcass and meat characteristics of the steers. The grass-legume mixture decreases the total concentration of unsaturated fatty acids in meat without influencing the concentration of polyunsaturated fatty acids.

animal production; annual grassland; Arachis pintoi; fatty acid; mixed pasture

1. Introduction

Nitrogen fertilization on forage production brings good results (Beck et al., 2017Beck, P.; Hess, T.; Hubbell, D.; Gadberry, M. S.; Jennings, J. and Sims, M. 2017. Replacing synthetic N with clovers or alfalfa in bermudagrass pastures. 1. Herbage mass and pasture carrying capacity. Animal Production Science 57:539-546. https://doi.org/10.1071/AN15045
https://doi.org/10.1071/AN15045... ), influencing animal productivity like the carrying capacity (Pontes et al., 2018Pontes, L. S.; Barro, R. S.; Savian, J. V.; Berndt, A.; Moletta, J. L.; Porfírio-da-Silva, V.; Bayer, C. and Carvalho, P. C. F. 2018. Performance and methane emissions by beef heifer grazing in temperate pastures and in integrated crop-livestock systems: The effect of shade and nitrogen fertilization. Agriculture, Ecosystems & Environment 253:90-97. https://doi.org/10.1016/j.agee.2017.11.009
https://doi.org/10.1016/j.agee.2017.11.0... ). However, there is some pressure to reduce the use of nitrogen fertilizers due to economic and environmental issues (Beck et al., 2017Beck, P.; Hess, T.; Hubbell, D.; Gadberry, M. S.; Jennings, J. and Sims, M. 2017. Replacing synthetic N with clovers or alfalfa in bermudagrass pastures. 1. Herbage mass and pasture carrying capacity. Animal Production Science 57:539-546. https://doi.org/10.1071/AN15045
https://doi.org/10.1071/AN15045... ). The replacement of nitrogen fertilizers by nitrogen fixation of legumes can be a potential alternative to substitute part of the nitrogen fertilization.

In tropical regions, the grass-legume mixture is rare, and single crops are more common (Muir et al., 2011Muir, J. P.; Pitman, W. D. and Foster, J. L. 2011. Sustainable, low-input, warm-season, grass-legume grassland mixtures: mission (nearly) impossible? Grass and Forage Science 66:301-315. https://doi.org/10.1111/j.1365-2494.2011.00806.x
https://doi.org/10.1111/j.1365-2494.2011... ). For the subtropical and warm-temperate latitudes, a wide range of persistent warm-season perennial grasses is available. They commonly occur as near-monoculture grass pastures. In this way, the use of legumes in pasture can promote some increases in animal production by improving the forage nutritional value (Beck et al., 2017Beck, P.; Hess, T.; Hubbell, D.; Gadberry, M. S.; Jennings, J. and Sims, M. 2017. Replacing synthetic N with clovers or alfalfa in bermudagrass pastures. 1. Herbage mass and pasture carrying capacity. Animal Production Science 57:539-546. https://doi.org/10.1071/AN15045
https://doi.org/10.1071/AN15045... ). This high nutritional value results from high levels of crude protein (CP) and high digestibility of forage legumes.

The most studied temperate legume in the world is white clover. However, under subtropical climate conditions, the persistence of this species is compromised by the hot and dry summers and its slow growth (Muir et al., 2011Muir, J. P.; Pitman, W. D. and Foster, J. L. 2011. Sustainable, low-input, warm-season, grass-legume grassland mixtures: mission (nearly) impossible? Grass and Forage Science 66:301-315. https://doi.org/10.1111/j.1365-2494.2011.00806.x
https://doi.org/10.1111/j.1365-2494.2011... ). An option, especially in grazing areas, is forage peanut (Arachis pintoi Krapovickas and Gregory). This legume represents a potentially viable alternative for mixed cropping systems in subtropical and tropical regions because of its high nutritional value, persistence, soil cover, shading and grazing tolerance, and fast growth (Barcellos et al., 2008Barcellos, A. O.; Ramos, A. K. B.; Vilela, L. and Martha Junior, G. B. 2008. Sustentabilidade da produção animal baseada em pastagens consorciadas e no emprego de leguminosas exclusivas, na forma de banco de proteína, nos trópicos brasileiros. Revista Brasileira de Zootecnia 37(suplemento especial):51-67. https://doi.org/10.1590/S1516-35982008001300008
https://doi.org/10.1590/S1516-3598200800... ; Costa et al., 2020Costa, O. A. D.; Ferreira, O. G. L.; Henrique, D. S.; Vaz, R. Z.; Fluck, A. C.; Paris, W.; Kröning, A. B.; Griffith, L. A. A. and Matos, O. I. T. 2020. Morphophysiology of forage peanut submitted to different intensities of defoliation on grazing with sheep. Tropical Animal Health and Production 52:547-554. https://doi.org/10.1007/s11250-019-02041-7
https://doi.org/10.1007/s11250-019-02041... ).

Finishing on pasture leads to a more significant deposition of n-3, CLA fatty acids, and a lower n-6:n-3 ratio in the meat than grain-finishing (Aldai et al., 2011Aldai, N.; Dugan, M. E. R.; Kramer, J. K. G.; Martínez, A.; López-Campos, O.; Mantecón, A. R. and Osoro, K. 2011. Length of concentrate finishing affects the fatty acid composition of grass-fed and genetically lean beef: an emphasis on trans-18: 1 and conjugated linoleic acid profiles. Animal 5:1643-1652. https://doi.org/10.1017/S1751731111000607
https://doi.org/10.1017/S175173111100060... ; Patino et al., 2015Patino, H. O.; Medeiros, F. S.; Pereira, C. H.; Swanson, K. C. and McManus, C. 2015. Productive performance, meat quality and fatty acid profile of steers finished in confinement or supplemented at pasture. Animal 9:966-972. https://doi.org/10.1017/S1751731115000105
https://doi.org/10.1017/S175173111500010... ). A higher concentration of linolenic acid facilitates the deposition of n-3 PUFA (polyunsaturated fatty acids) in the muscle and is often found in pasture. Although higher levels of PUFA are associated with higher lipid oxidation (Mello et al., 2012Mello, A. S.; Calkins, C. R.; Jenschke, B. E.; Carr, T. P.; Dugan, M. E. R. and Erickson, G. E. 2012. Beef quality of calf-fed steers finished on varying levels of corn-based wet distillers grains plus solubles. Journal of Animal Science 90:4625-4633. https://doi.org/10.2527/jas.2010-3239
https://doi.org/10.2527/jas.2010-3239... ), pasture is a natural source of antioxidants (Lindqvist et al., 2012Lindqvist, H.; Nadeau, E. and Jensen, S. K. 2012. Alpha-tocopherol and β-carotene in legume-grass mixtures as influenced by wilting, ensiling and type of silage additive. Grass and Forage Science 67:119-128. https://doi.org/10.1111/j.1365-2494.2011.00827.x
https://doi.org/10.1111/j.1365-2494.2011... ), which lowers lipid oxidation rates that are usually observed in grass-finished beef. However, studies evaluating carcass characteristics and fatty acid profile of beef cattle finished on pasture of temperate grasses overseeded in tropical pasture with or without legumes are scarce in the literature. Thus, the hypothesis of this research is to determine whether the inclusion of a perennial tropical legume changes the carcass characteristics, quality, and fatty acid profile of the meat of finished cattle, exclusively on pasture.

2. Material and Methods

2.1. Location, area, and soil fertility management

The experimental area was in Dois Vizinhos, Paraná state, Brazil (elevation of 520 m above sea level, 25°44' South and 53°04' West). The soil is classified as Dystroferric Red Nitosol. The climate is humid subtropical mesothermal (Cfa) according to the Köppen criteria. The total rainfall of the experimental period (June – September) was 650 mm, with average temperatures between 14 and 21 °C.

In September 2013, the Megathyrsus maximus (Jacq.) B.K. Simon & S.W.L. Jacobs cv. Aruana, was seeded in nine paddocks using a seeder with 17 cm of row spacing (5 kg of viable seeds/ha). The legume (Arachis pintoi Krapovickas and Gregory cv. Amarillo) was distributed in 3 m wide (10 kg of seeds/ha) in three paddocks, which was 30% of the experimental area. During the summer, the cattle used to graze in all paddocks, until the temperate grasses was established.

Soil analysis at the beginning of the experiment showed the following results (0–20 cm): pH (CaCl₂) = 5.0; MO = 29 g/dm³; carbon = 20.1 g/dm³; argil = 64%; P-Mehlich = 3.7 mg/dm³; K = 0.2 cmolc/dm³; Ca KCl = 4.5 cmolc/dm³; Mg = 2.5 cmolc/dm³; H+Al = 5.8 cmolc/dm³; base sum = 7.3 cmolc/dm³; CTC effective = 13 cmolc/dm³; saturation Al = 1.4%; base saturation = 56%. Based on the soil analysis results and recommendations of the CQFS RS/SC (2004)CQFS RS/SC - Comissão de Química e Fertilidade do Solo. 2004. Manual de adubação e de calagem para os estados do Rio Grande do Sul e de Santa Catarina. 10.ed. Sociedade Brasileira de Ciência do Solo, Comissão de Química e Fertilidade do Solo, Porto Alegre., for grass-legume mixture, the base fertilization happened at the seeding of the temperate grasses; for that, 80 kg/ha of P₂O₅ and 100 kg/ha of K₂O were applied together with the first nitrogen fertilization. Ryegrass (Lolium multiflorum Lam. ‘Fepagro São Gabriel’ - 30 kg of seed/ha) and black oat (Avena strigosa Schreb ‘IAPAR 61’ - 60 kg/ha of pure and viable seeds) were seeded in line with 17 cm spacing, in April 2016. The overseeding was carried out with the Aruana pasture at 15 cm.

2.2. Experimental design and treatments

The experimental design was in completely randomized design with three replicates. The experiment was carried out during winter and spring 2016, from June to October, with 18 days for adaptation and 109 days for evaluations. The experimental area had nine paddocks, 0.7 ha each, with a total area of 6.3 ha. Treatments were: 100 kg N/ha (Low-N), 200 kg N/ha (Medium-N) and, 100 kg/ha of N with the Arachis pintoi-Aruana grass mixture (Legume). The topdressing of urea (45% of N) had five applications according to each treatment, on the following dates: 06/01/2016, 06/25/2016, 07/21/2016, 08/19/2016, and 09/03/2016.

2.3. Pasture management and evaluation

The pasture was managed under a continuous stocking rate, with the put-and-take adjustment method (Mott and Lucas, 1952Mott, G. O. and Lucas, H. L. 1952. The design, conduct and interpretation of grazing trials on cultivated and improved pastures. p.1380-1385. In: Proceedings of the Sixth International Grassland Congress. Pennsylvania State College, State College, PA.). Two tester animals were used per paddock. Forage mass (FM) was estimated for each period of 21 days through the double sampling technique, with 20 visual estimates and five clips per paddock (Wilm et al., 1944Wilm, H. G. G.; Costello, D. F. and Klipple, G. E. 1944. Estimating forage yield by the double-sampling method. Agronomy Journal 36:194-203. https://doi.org/10.2134/agronj1944.00021962003600030003x
https://doi.org/10.2134/agronj1944.00021... ). Simultaneously, pasture height was measured using a ruler in 20 spots. Forage accumulation rate was measured by two exclusion cages per paddock for each period of 21 days. Arachis pintoi mass contribution was estimated after botanical and sample separation; the value was 18% (total dry matter [DM] yield) throughout the experiment. Forage mass and structural composition of the pasture are presented in Schmitz et al. (2019)Schmitz, G. R.; Paris, W.; Biesek, R. R.; Costa, O. A. D.; Mafioletti, R. D.; Umezaki, A. M. and Menezes, L. F. G. 2019. Partial replacement of nitrogen fertilization with legumes in tropical pasture overseeded with temperate species for the production of steers. The Journal of Agricultural Science 157:628-635. https://doi.org/10.1017/S0021859619000893
https://doi.org/10.1017/S002185961900089... .

Forage allowance (FA) was calculated as described by Sollenberger et al. (2005)Sollenberger, L. E.; Moore, J. E.; Allen, V. G. and Pedreira, C. G. S. 2005. Reporting forage allowance in grazing experiments. Crop Science 45:896-900. https://doi.org/10.2135/cropsci2004.0216
https://doi.org/10.2135/cropsci2004.0216... , according to the equation: $F A = ({F M}_{mean}) / (k g L W / h a)$ , in which FM = forage mass, calculated as $(({F M}_{cut 1} + {F M}_{cut 2}) / 2)$ , and LW = live weight. Stocking rate (SR) was calculated as the sum of the tester animals’ live weight, corrected to the area size, and added to the weight of the grazing-height regulator animals, taking into account the number of days that the regulators remained in each paddock. The management criterion for adjusting the SR was the estimated FA of 8% body weight (BW) during the entire grazing period.

The samples for the chemical analysis (Table 1) of the pasture were obtained, for each period of 21 days, through the hand-plucking method (Moore and Sollenberger, 1997Moore, J. E. and Sollenberger, L. E. 1997. Techniques to predict pasture intake. p.81-96. In: Simpósio Internacional sobre Produção Animal em Pastejo. Universidade Federal de Viçosa, Departamento de Zootecnia, Viçosa, MG.). Samples were dried in a forced-air oven at 55 ℃ for 72 h to obtain the partially dried samples, and ground in a Wiley-type mill™ (Thomas Scientific^®) fitted with a 1-mm-sieve. The DM, ash, organic matter (OM), and CP analyses were performed according to AOAC (2012)AOAC - Association of Official Analytical Chemists. 2012. Official methods of analysis. 19th ed. AOAC International, Gaithersburg.. The neutral detergent insoluble fiber was determined by the method proposed by Van Soest et al. (1991)Van Soest, P. J.; Robertson, J. B. and Lewis, B. A. 1991. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. Journal of Dairy Science 74:3583-3597. https://doi.org/10.3168/jds.S0022-0302(91)78551-2
https://doi.org/10.3168/jds.S0022-0302(9... , adapted for the ANKOM2000 apparatus (ANKOM A2000 Fiber Analyzer, ANKOM Technology Corporation, Fairport, NY, USA) using filter bags. The in vitro DM digestibility (IVDMD) was estimated with filter bags (Tilley and Terry, 1963Tilley, J. M. A. and Terry, R. A. 1963. A two-stage technique for the in vitro digestion of forage crops. Grass and Forage Science 18:104-111. https://doi.org/10.1111/j.1365-2494.1963.tb00335.x
https://doi.org/10.1111/j.1365-2494.1963... ; Komarek, 1993Komarek, A. R. 1993. A fiber bag procedure for improved efficiency of fiber analyses. Journal of Dairy Science 76(suppl.1):250-259.) through a TECNAL^® TE-150 in vitro incubator and a detergent solution treatment (Goering and Van Soest, 1970Goering, H. K. and Van Soest, P. J. 1970. Forage fiber analysis (apparatus, reagents, procedures, and some applications). Agricultural Handbook No. 379. Agricultural Research Service, United States Department of Agriculture, Washington, D.C.) using the ANKOM^® Fiber Analyzer A2000. Total digestible nutrients (TDN) were calculated with the following equation: $TDN = % O M * [(26.8 + 0.595) * (IVOMD)) / 100]$ (Kunkle and Bates, 1998Kunkle, W. E. and Bates, D. B. 1998. Evaluating feed purchasing options: energy, protein, and mineral supplements. p.59-70. In: 47th Annual Florida Beef Cattle Short Course. University of Florida, Gainesville.), in which IVOMD = in vitro organic matter digestibility.

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Table 1
Chemical composition of Aruana grass overseeded with winter grasses subjected to nitrogen fertilization or grass-legume mixture obtained through simulated grazing

2.4. Animal, carcass and meat evaluations

The steers began grazing on 06/13/2016, when the pasture reached an average sward height of 23±1.5 cm and forage mass of 1940±232 kg DM/ha. Twenty-four crossbred steers (1/4 Marchegiana, 1/4 Aberdeen Angus, and 2/4 Nelore), at 21±2 months old and an initial live weight of 412±8.2 kg, were used. The animals had free access to water and mineral salt.

We assessed the average daily gain (ADG, kg/animal) through two weightings of each tester animal during the grazing, which was at the beginning and the end of each experimental period with a fasting of 14 h before the weighing. All animals were slaughtered when the average subcutaneous fat thickness in all treatments reached a minimum of 3.0 mm. We took this measure during weighing through in vivo ultrasonography performed between the 12th and 13th ribs. Animals were slaughtered in a slaughterhouse, according to the laws of humane slaughter. The carcass characteristics were measured using the methodology described by Müller (1987)Müller, L. 1987. Normas para avaliação de carcaças e concurso de carcaça de novilhos. 2.ed. Universidade Federal de Santa Maria, Santa Maria.. The two half carcasses were weighed to obtain the hot carcass weight (HCW) and the hot dressing percentage $(H C P = H C W / S L W \times 100)$ , in which SWL = slaughter live weight. The cold carcass weight (CCW) and cold dressing percentage $(C D P = C C W / S L W \times 100)$ were obtained after cooling in a chill room at 0 °C for 24 h.

In the right half cold carcass, we made the cut of the HH section (Hankins and Howe, 1946Hankins, O. G. and Howe, P. E. 1946. Estimation of the composition of beef carcasses and cuts. Technical Bulletin No. 926. United States Department of Agriculture, Washington, D.C.) modified by Müller (1987)Müller, L. 1987. Normas para avaliação de carcaças e concurso de carcaça de novilhos. 2.ed. Universidade Federal de Santa Maria, Santa Maria. with the cut between the 11th and 12th ribs. The physical separation of tissues in muscles, fat, and bone was carried out to determine the total quantity and cold carcass percentage from that cut. In that same section, at the height of the 12th rib, the surface of the longissimus dorsi muscle was exposed. After at least 30 min of exposure to air, we performed evaluations of color, texture, and marbling of the meat, assigning scores from 1 to 5. The CIE Lab System was implemented, and color measurements were recorded for the L*(lightness), a* (redness), and b* (yellowness) values. For this, we used a portable spectrophotometer CM-600D (Konica Minolta Sensing Inc, Osaka, Japan) equipped with illuminant A, 8 mm aperture, and a 10° standard observer. Average color values were recorded at three random points on the meat surface, keeping a distance of 1 cm from the edge of the piece.

Samples of the longissimus dorsi were taken from the cuts, identified, vacuum packed, wrapped with brown paper, and immediately frozen at −18 °C. From the samples still frozen, three cuts of 2.5 cm thickness were taken. The cut “A” was weighed to determine the loss during thawing and then cooked at an internal meat temperature of 70 °C for 15 min to assess the possible losses in the cooking. After cooking the cut “B”, three samples of 1 cm² were taken in the perpendicular direction to the muscle fibers, and in each one, two readings were performed by a Warner Bratzler Shear device to determine the meat shear force (Destefanis et al., 2008Destefanis, G.; Brugiapaglia, A.; Barge, M. T. and Dal Molin, E. 2008. Relationship between beef consumer tenderness perception and Warner-Bratzler shear force. Meat Science 78:153-156. https://doi.org/10.1016/j.meatsci.2007.05.031
https://doi.org/10.1016/j.meatsci.2007.0... ). Still, the longissimus dorsi samples were used to obtain the fatty acids methyl esters, following the adapted method described by Giotto et al. (2020)Giotto, F. M.; Fruet, A. P. B.; Nörnberg, J. L.; Calkins, C. R. and Mello, A. S. 2020. Effects of muscle and finishing diets containing distillers grains with low moisture levels on fatty acid deposition in two novel value-added beef cuts. Food Science and Animal Resources 40:484-494. https://doi.org/10.5851/kosfa.2020.e28
https://doi.org/10.5851/kosfa.2020.e28... . The determination was made in a gas chromatograph equipped with a flame ionization detector and Supelco SP2340 capillary column (60 m × 0.25 mm × 0.2 µm). Detector and injector temperatures were 260 and 240 °C, respectively. The column heating schedule was started at 140 °C for 5 min, gradually increased 4 °C per minute to the final temperature of 240 °C, and finally maintained for 5 min. The entrainment gas flow (H₂) was 17 mL/min. The injection volume was 0.5 μL with a split ratio of 1:100. Peak identification, as well as quantification, were done by comparing the retention times and peak area of the samples with those of fatty acid methyl esters (Supelco 37 components FAMEs Mix, ref. 47885-U).

2.5. Statistical analysis

Data were analyzed in a completely randomized design, with three replicates. The N doses and legume were considered fixed effects. For the pasture characteristics and animal performance, the animal, period, interaction period × treatment, and the residual error were used in the model as random variables. For the post-mortem variables, we did not use period and interaction effects. For the forage evaluation, the paddock was the experimental unit. For animal performance, carcass, meat evaluation, and fatty acids profile, each animal was considered as an experimental unit, being a random effect f according to the model:

Y_{i j j k} = μ + α_{i} + p_{j} + a_{k} + {(α^{*} p)}_{i j} + ε_{i j k}

in which Y_ijk is the observation concerning the i-th N and legume used (α_i) in the j-th grazing period (p_j) and k-th animal (a_k). Data were submitted to analysis of variance with the Glimmix procedure of SAS (Statistical Analysis System, 2013) using generalized linear mixed models. Then, the variables were compared through the Tukey-Kramer test (P = 0.05) only when the effect of treatments was significant. The marbling score was analyzed by the Npar1way procedure of SAS in a Dwass-Steel-Critchlow-Fligner (DSCF) multiple comparison analysis.

3. Results

There was a difference between the concentrations of fatty acids in the grazing simulation samples (Table 2). The pasture with legumes showed a higher concentration of saturated fatty acids (SFA) and a higher SFA to unsaturated fatty acids (UFA) ratio. Single grass pastures had a higher content of monounsaturated fatty acids (MUFA) and PUFA than the mixed pastures. The N fertilization without legume presented a higher sward height (Table 3). Still, the N increase (Medium-N) resulted in higher forage mass yield. Forage allowance, SR, and ADG did not show any difference.

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Table 2
Fatty acids profile of Aruana grass overseeded with winter grasses subjected to nitrogen fertilization or grass-legume mixture obtained through simulated grazing

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Table 3
Minimum mean squares of animal daily gain and pasture characteristics of Aruana grass overseeded with winter grasses subjected to nitrogen fertilization or grass-legume mixture

There was no treatment effect on the carcass and meat characteristics (Table 4). In general, we observed high hot dressing percentage (56.48%). However, the rib fat thickness (+ 2.74 mm) and marbling score (µ = 3.4 points; median = 3.0) were low. The UFA profile showed a difference between treatments, with higher values for pasture without legume (Table 5). Still, the SFA:UFA ratio showed lower values for this treatment (no legume).

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Table 4
Minimum mean squares of carcass and meat characteristics of finished steers on Aruana grass overseeded with winter grasses subjected to nitrogen fertilization or grass-legume mixture

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Table 5
Minimum mean squares of the main fatty acids (%) found in the longissimus muscle of steers on Aruana grass overseeded with winter grasses subjected to nitrogen fertilization or grass-legume mixture

4. Discussion

The higher content of SFA in the grass-legume pastures than in single grasses can be explained by the fact that growing grasses mixed with legumes may decrease the sugar content of fresh forages compared with single grasses (Brown et al., 2018Brown, A. N.; Ferreira, G.; Teets, C. L.; Thomason, W. E. and Teutsch, C. D. 2018. Nutritional composition and in vitro digestibility of grass and legume winter (cover) crops. Journal of Dairy Science 101:2037-2047. https://doi.org/10.3168/jds.2017-13260
https://doi.org/10.3168/jds.2017-13260... ). Besides, plants need to synthesize PUFA to ensure fluidity of their membranes at low temperatures (Beltrão and Oliveira, 2007Beltrão, N. E. M. and Oliveira, M. I. P. 2007. Biossíntese e degradação de lipídios, carboidratos e proteínas em oleaginosas. Documentos, 178. Embrapa Algodão, Campina Grande. 61p.). As black oat and ryegrass are more adapted to low temperatures, they may have higher UFA levels.

Forage mass and sward height differences were not sufficient to affect the animal performance as FA was similar in all treatments (Table 3). Forage mass remained above 1,200 kg DM/ha, which allowed the animals to choose a diet with a high nutritional value in all treatments. We worked around these differences by adjusting the SR, as the pasture allowance was the same for all treatments. Arachis pintoi accounted for 18% of the FM (+ 245 kg DM). These forage amounts may have contributed to the increase of species diversity and the beginning of growth before the spring.

We did not observe any increase in animal performance in the treatment with Arachis pintoi due to the similar nutritional values (Table 1) observed in the samples obtained by the grazing simulation technique. According to Barcellos et al. (2008)Barcellos, A. O.; Ramos, A. K. B.; Vilela, L. and Martha Junior, G. B. 2008. Sustentabilidade da produção animal baseada em pastagens consorciadas e no emprego de leguminosas exclusivas, na forma de banco de proteína, nos trópicos brasileiros. Revista Brasileira de Zootecnia 37(suplemento especial):51-67. https://doi.org/10.1590/S1516-35982008001300008
https://doi.org/10.1590/S1516-3598200800... , there is a lower animal preference for legumes in tropical regions than grasses and, consequently, a trend for choosing grasses. Similar results (Lazzarotto et al., 2019Lazzarotto, E. F. C. O.; Menezes, L. F. G.; Paris, W.; Molinete, M. L.; Schmitz, G. R.; Baraviera, J. H. I.; Farenzena, R. and Paula, A. L. 2019. Backgrounding steers on temperate grasses mixed with vetch and/or using energy supplementation. Asian-Australasian Journal of Animal Sciences 32:800-807. https://doi.org/10.5713/ajas.18.0603
https://doi.org/10.5713/ajas.18.0603... ; Lisbinski et al., 2019Lisbinski, E.; Ronsani, R.; Assis Farias, J.; Paris, W.; Farenzena, R.; Stanqueviski, F. and Menezes, L. F. G. 2019. Performance and ingestive behavior of steers on integrated system using legume and/or energy supplementation. Tropical Animal Health and Production 51:205-211. https://doi.org/10.1007/s11250-018-1678-4
https://doi.org/10.1007/s11250-018-1678-... ) were found in other studies, and the authors verified similar gains between animals on oat + ryegrass pastures mixed with vetch and those that only grazed grasses.

Diet quality is one of the main factors influencing carcass and meat quality (Duckett et al., 2013Duckett, S. K.; Neel, J. P. S.; Lewis, R. M.; Fontenot, J. P. and Clapham, W. M. 2013. Effects of forage species or concentrate finishing on animal performance, carcass and meat quality. Journal of Animal Science 91:1454-1467. https://doi.org/10.2527/jas.2012-5914
https://doi.org/10.2527/jas.2012-5914... ). In our study, we did not observe any difference between the treatments on the carcass characteristics due to the similar diet nutritional quality between treatments and the similarity in animal performance (Table 4). Likewise, Moloney et al. (2018)Moloney, A. P.; O’Riordan, E. G.; Schmidt, O. and Monahan, F. J. 2018. The fatty acid profile and stable isotope ratios of C and N of muscle from cattle that grazed grass or grass/clover pastures before slaughter and their discriminatory potential. Irish Journal of Agricultural and Food Research 57:84-94. observed that dressing percentage was similar for cattle that grazed a grass-legume pasture and those that grazed fertilized grass, highlighting the potential cost reduction due to the replacement of inorganic N fertilizer by Arachis pintoi.

The slaughtering point was achieved when the average fat thickness of all treatments reached 3 mm, measured through an ultrasound. However, the measurement of the ultrasound device is not 100% reliable (Suguisawa et al., 2006Suguisawa, L.; Mattos, W. R. S.; Souza, A. A.; Silveira, A. C.; Oliveira H. N.; Arrigoni M. B. and Burini D. C. M. 2006. Ultra-sonografia para predição da composição da carcaça de bovinos jovens. Revista Brasileira de Zootecnia 35:177-185. https://doi.org/10.1590/S1516-35982006000100023
https://doi.org/10.1590/S1516-3598200600... ), explaining why the actual thickness was lower than the one observed before slaughter. Also, during the hide removal of the animal, the adipose tissue may adhere to the hide walls, which adversely affects the fat thickness. Another circumstance that negatively affected the fat deposition in the carcasses was the pasture energy level (Table 1). The cattle gain becomes predominantly adipose tissue in the finishing phase, with a lower protein requirement and a high energy requirement for fat deposition and marbling. In this context, Ducket et al. (2013) reported that in the presence of legumes, animals tend to decrease the energy intake, which affects the deposition of subcutaneous fat in carcasses. The increasing degradability of dietary protein leads to ruminal ammonia production, resulting in a higher N loss through urine and feces (Agle et al., 2010Agle, M.; Hristov, A. N.; Zaman, S.; Schneider, C.; Ndegwa, P. and Vaddella, V. K. 2010. The effects of ruminally degraded protein on rumen fermentation and ammonia losses from manure in dairy cows. Journal of Dairy Science 93:1625-1637. https://doi.org/10.3168/jds.2009-2579
https://doi.org/10.3168/jds.2009-2579... ). Consequently, the net energy storage for maintenance, growth, and fat reserves is lower due to excess dietary protein, resulting in lower animal performance (Wright et al., 2015Wright, A. M.; Andrae, J. G.; Rosso, C. F., Miller, M. C.; Pavan, E.; Bridges, W. and Duckett, S. K. 2015. Effect of forage type with or without corn supplementation on animal performance, beef fatty acid composition, and palatability. Journal of Animal Science 93:5047-5058. https://doi.org/10.2527/jas.2015-8939
https://doi.org/10.2527/jas.2015-8939... ).

Several studies demonstrated the lack of effects of legumes on carcass and meat quality. Jaturasitha et al. (2009)Jaturasitha, S.; Norkeaw, R.; Vearasilp, T.; Wicke, M. and Kreuzer, M. 2009. Carcass and meat quality of Thai native cattle fattened on Guinea grass (Panicum maximum) or Guinea grass-legume (Stylosanthes guianensis) pastures. Meat Science 81:155-162. https://doi.org/10.1016/j.meatsci.2008.07.013
https://doi.org/10.1016/j.meatsci.2008.0... did not find any effect of a tropical legume (Stylosanthes guianensis) on the carcass and meat quality of the steers, while Moloney et al. (2018)Moloney, A. P.; O’Riordan, E. G.; Schmidt, O. and Monahan, F. J. 2018. The fatty acid profile and stable isotope ratios of C and N of muscle from cattle that grazed grass or grass/clover pastures before slaughter and their discriminatory potential. Irish Journal of Agricultural and Food Research 57:84-94. obtained similar results when they included white clover in ryegrass pasture. Some authors point out the need for further studies on legumes influencing meat sensory analysis (Mapiye et al., 2011Mapiye, C.; Chimonyo, M.; Dzama, K.; Hugo A.; Strydom P. E. and Muchenje V. 2011. Fatty acid composition of beef from Nguni steers supplemented with Acacia karroo leaf-meal. Journal of Food Composition and Analysis 24:523-528. https://doi.org/10.1016/j.jfca.2011.01.018
https://doi.org/10.1016/j.jfca.2011.01.0... ). Animals deposit a lower iron content in the meat (Jaturasitha et al., 2009Jaturasitha, S.; Norkeaw, R.; Vearasilp, T.; Wicke, M. and Kreuzer, M. 2009. Carcass and meat quality of Thai native cattle fattened on Guinea grass (Panicum maximum) or Guinea grass-legume (Stylosanthes guianensis) pastures. Meat Science 81:155-162. https://doi.org/10.1016/j.meatsci.2008.07.013
https://doi.org/10.1016/j.meatsci.2008.0... ) in legume pastures, resulting in light-colored muscles. However, Mapiye et al. (2011)Mapiye, C.; Chimonyo, M.; Dzama, K.; Hugo A.; Strydom P. E. and Muchenje V. 2011. Fatty acid composition of beef from Nguni steers supplemented with Acacia karroo leaf-meal. Journal of Food Composition and Analysis 24:523-528. https://doi.org/10.1016/j.jfca.2011.01.018
https://doi.org/10.1016/j.jfca.2011.01.0... reported that cattle fed sweet thorn (Acacia karroo) presented red meat, mainly related to the high intake of dietary iron.

Legumes in the pasture can alter the rumen environment, mainly due to the type of fiber of these plants, which can affect the type of fatty acid synthesized by the ruminal microbiota. Still, even with the lowest concentration of UFA in the meat of beef steers from the grass-legume mixture (Table 5), there was no difference in PUFA, being a response to treatment with Arachis pintoi in which the pasture presented a high concentration of SFA, low UFA, and no change in the proportion of PUFA (Table 2). Also, phenolic compounds, such as lignin, can affect the biohydrogenation of PUFA (Kalač and Samková, 2010Kalač, P. and Samková, E. 2010. The effects of feeding various forages on fatty acid composition of bovine milk fat: a review. Czech Journal of Animal Science 55:521-537. https://doi.org/10.17221/2485-CJAS
https://doi.org/10.17221/2485-CJAS... ).

The literature reports improvements in the fatty acids profile in the meat of animals that consumed legumes, particularly in relation to PUFA. The red and, especially, white clover were clearly beneficial by decreasing the n-6:n-3 fatty acid ratio in milk even though the clover lipids are not necessarily superior to the grass in that respect (Dewhurst et al., 2006Dewhurst, R. J.; Shingfield, K. J.; Lee, M. R. F. and Scollan, N. D. 2006. Increasing the concentrations of beneficial polyunsaturated fatty acids in milk produced by dairy cows in high-forage systems. Animal Feed Science and Technology 131:168-206. https://doi.org/10.1016/j.anifeedsci.2006.04.016
https://doi.org/10.1016/j.anifeedsci.200... ; Van Dorland et al., 2008Van Dorland, H. A.; Kreuzer, M.; Leuenberger, H. and Wettstein, H. R. 2008. Comparative potential of white and red clover to modify the milk fatty acid profile of cows fed ryegrass-based diets from zero-grazing and silage systems. Journal of the Science of Food and Agriculture 88:77-85. https://doi.org/10.1002/jsfa.3024
https://doi.org/10.1002/jsfa.3024... ). Scollan et al. (2006)Scollan, N.; Hocquette, J.-F.; Nuernberg, K.; Dannenberger, D.; Richardson, I. and Moloney, A. 2006. Innovations in beef production systems that enhance the nutritional and health value of beef lipids and their relationship with meat quality. Meat Science 74:17-33. https://doi.org/10.1016/j.meatsci.2006.05.002
https://doi.org/10.1016/j.meatsci.2006.0... found that increasing levels of red clover substituting ryegrass may result in a significant decline in the n6:n3 ratio of beef. This response is mainly owing to the higher concentration of C18:3 in these forages, which was not observed in the present study. Fruet et al. (2018)Fruet, A. P. B.; Trombetta, F.; Stefanello, F. S.; Speroni, C. S.; Donadel, J. Z.; De Souza, A. N. M.; Rosado Júnior, A.; Tonetto, C. J.; Wagner, R.; De Mello, A. and Nörnberg, J. L. 2018. Effects of feeding legume-grass pasture and different concentrate levels on fatty acid profile, volatile compounds, and off-flavor of the M. longissimus thoracis. Meat Science 140:112-118. https://doi.org/10.1016/j.meatsci.2018.03.008
https://doi.org/10.1016/j.meatsci.2018.0... evaluated finishing cattle on legume-grass pasture compared to animals fed only with grains. They observed that the finishing system did not affect CP, SFA, PUFA, and PUFA:SFA ratio. However, the animals without roughage presented lower C18:0 and higher concentrations of C18:1n7, C18:1trans, and MUFA than steers finished on legume-grass pasture. Beef from steers fed diets with roughage had a low n-6:n-3 ratio and high values of C18:2cis-9 trans-11, C18:3n3, and total n-3.

However, there is little information on the effect of tropical legumes on the fatty acid profile of beef. Jaturasitha et al. (2009)Jaturasitha, S.; Norkeaw, R.; Vearasilp, T.; Wicke, M. and Kreuzer, M. 2009. Carcass and meat quality of Thai native cattle fattened on Guinea grass (Panicum maximum) or Guinea grass-legume (Stylosanthes guianensis) pastures. Meat Science 81:155-162. https://doi.org/10.1016/j.meatsci.2008.07.013
https://doi.org/10.1016/j.meatsci.2008.0... did not observe any effect when they included Stylosanthes in the pasture. In the present study, Arachis pintoi decreased the percentage of UFA and increased the SFA:UFA ratio of pasture and meat of the animals when they were finished with mixed forages of high nutritional value.

5. Conclusions

The inclusion of Arachis pintoi or an increase in nitrogen fertilizer in Aruana grass pasture overseeded with black oat and ryegrass does not change the daily weight gain and carcass and meat characteristics of steers in the finishing phase. Including Arachis pintoi in grass pastures decreases the concentration of unsaturated fatty acids and increases the saturated:unsaturated fatty acids ratio in the pasture and meat without affecting the concentration of polyunsaturated fatty acids.

Acknowledgments

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, Brazil (CAPES; Finance Code 001), and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Brazil – Process 477966/2013-6. The authors would like to thank the Bromatologia Animal Multiuser Laboratory from the Universidade Tecnológica Federal do Paraná, Campus Dois Vizinhos, for the performed analyses.

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Publication Dates

Publication in this collection
10 July 2023
Date of issue
2023

History

Received
26 Mar 2021
Accepted
3 Feb 2023

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Agle, M.; Hristov, A. N.; Zaman, S.; Schneider, C.; Ndegwa, P. and Vaddella, V. K. 2010. The effects of ruminally degraded protein on rumen fermentation and ammonia losses from manure in dairy cows. Journal of Dairy Science 93:1625-1637. https://doi.org/10.3168/jds.2009-2579
» https://doi.org/10.3168/jds.2009-2579

[2] Aldai, N.; Dugan, M. E. R.; Kramer, J. K. G.; Martínez, A.; López-Campos, O.; Mantecón, A. R. and Osoro, K. 2011. Length of concentrate finishing affects the fatty acid composition of grass-fed and genetically lean beef: an emphasis on trans-18: 1 and conjugated linoleic acid profiles. Animal 5:1643-1652. https://doi.org/10.1017/S1751731111000607
» https://doi.org/10.1017/S1751731111000607

[3] AOAC - Association of Official Analytical Chemists. 2012. Official methods of analysis. 19th ed. AOAC International, Gaithersburg.

[4] Barcellos, A. O.; Ramos, A. K. B.; Vilela, L. and Martha Junior, G. B. 2008. Sustentabilidade da produção animal baseada em pastagens consorciadas e no emprego de leguminosas exclusivas, na forma de banco de proteína, nos trópicos brasileiros. Revista Brasileira de Zootecnia 37(suplemento especial):51-67. https://doi.org/10.1590/S1516-35982008001300008
» https://doi.org/10.1590/S1516-35982008001300008

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Chemical composition	Treatment¹

	Medium-N	Legume	Low-N
Dry matter (DM, %)	19.24	20.82	21.52
Ash (% DM)	12.48	12.47	12.39
Crude protein (% DM)	28.07	28.15	27.63
Neutral detergent insoluble fiber (% DM)	46.30	46.67	47.80
Acid detergent insoluble fiber (% DM)	26.19	25.92	27.19
Dry matter digestibility (% DM)	75.71	76.50	75.01
Total digestible nutrients (% DM)	62.18	62.87	62.13

Fatty acids (% fat)	Treatment¹			SEM	P-value

	Medium-N	Legume	Low-N
Lauric (C12:0)	0.41	0.00	0.65	0.20	0.5519
Myristic (C14:0)	1.56	1.15	1.44	0.25	0.5448
Palmitic (C16:0)	23.24	22.45	23.57	0.90	0.7141
Margaric (C17:0)	0.77	0.56	1.02	0.20	0.4307
Stearic (C18:0)	8.82	6.95	8.53	1.12	0.5216
SFA	51.09b	59.65a	54.82ab	1.61	0.0183
Palmitoleic (C16:1)	1.77	1.54	1.89	0.29	0.7293
Oleic (C18:1)	22.70	16.19	18.07	4.15	0.5779
MUFA	41.01a	31.18b	37.13ab	1.35	0.0121
Linoleic (C18:2)	6.72	8.04	7.15	0.60	0.3569
Linolenic (C18:3)	0.52	0.41	0.73	0.23	0.6433
PUFA	7.89	9.17	8.05	0.65	0.4233
UFA	48.90a	40.34b	45.18ab	1.24	0.0149
SFA/UFA	1.05b	1.48a	1.22ab	0.06	0.0167

	Treatment¹			SEM	P-value

	Medium-N	Legume	Low-N
Sward height (cm)	12.36a	8.95b	10.40ab	0.61	0.0322
Forage mass (kg/ha)	1467.29a	1301.73b	1376.02b	18.46	0.0033
Forage allowance (kg/ha)	1.089	0.977	1.034	0.057	0.1477
Stocking rate (kg/ha)	1343.10	1340.35	1327.34	64.30	0.9693
Average daily gain (kg/day)	0.864	0.809	0.892	0.161	0.2283

	Treatment¹			SEM	P-value

	Medium-N	Legume	Low-N
Slaughter weight (kg)	517.00	515.50	531.83	17.09	0.7646
Hot carcass weight (kg)	291.05	290.70	302.50	11.52	0.7214
Cold carcass weight (kg)	286.90	286.80	297.58	11.35	0.7501
Cooling loss (%)	1.43	1.34	1.62	0.07	0.0531
Hot dressing (%)	56.27	56.39	56.79	0.80	0.8943
Cold dressing (%)	55.47	55.64	55.87	0.77	0.9358
Rib fat thickness (mm)	2.33	2.17	2.67	0.37	0.6376
Marbling (scores)²	2.60	3.40	3.0	0.93	0.8847
Carcass composition
Carcass lean (%)	68.61	64.55	68.03	1.26	0.0705
Carcass fat (%)	12.37	14.08	12.58	1.32	0.6205
Carcass bone (%)	19.03	21.39	19.03	0.68	0.0754
Cooking loss (%)	20.77	22.61	19.99	1.39	0.4157
Shear force (kgF)	8.43	7.21	8.31	0.69	0.3957
Lean lightness (L*)	36.48	36.42	37.62	1.28	0.7661
Lean redness (a*)	17.97	19.26	19.76	0.88	0.3482
Lean yellowness (b*)	8.76	8.65	10.29	0.77	0.3162

Fatty acid (% fat)	Treatment¹			SEM	P-value

	Medium-N	Legume	Low-N
Lauric (C12:0)	0.59	0.34	0.79	0.27	0.4477
Myristic (C14:0)	54.82ab	51.09b	59.65a	2.06	0.0297
Palmitic (C16:0)	22.89	23.65	22.49	0.18	0.4967
Margaric (C17:0)	0.94	1.03	0.94	0.03	0.6403
Stearic (C18:0)	17.21	19.06	17.00	0.40	0.2562
Arachidic (20:0)	0.55	0.36	0.19	0.18	0.2574
Lignoceric (24:0)	1.03	1.42	1.14	0.14	0.2265
SFA	47.20	50.02	47.23	0.86	0.0540
Palmitoleic (C16:1)	2.15	1.83	1.86	0.18	0.4453
Oleic (C18:1)	33.50	28.89	31.62	1.44	0.1334
Elaidic (18:1)	2.09	2.53	2.19	0.94	0.7118
Gondoic (20:1)	2.37	2.79	3.04	0.43	0.5280
Nervonic (24:1)	0.85	0.30	0.26	0.15	0.0594
MUFA	39.19	34.51	36.99	2.01	0.2818
Linoleic (18:2n6)	6.88	7.67	8.59	0.05	0.6942
Linoleic (18:2n6 t9t12)	0.27	0.19	0.30	0.02	0.2444
Linoleic (18:2cis-9 trans-11)²	0.50	0.49	0.52	0.06	0.9447
γ-Linolenic (18:3)	0.22	0.12	0.38	0.45	0.5021
α-Linolenic (18:3)	0.13	0.27	0.12	0.47	0.0599
Arachidonic (20:4)	2.58	3.33	2.70	0.17	0.4969
PUFA	11.79	13.28	14.16	2.00	0.6972
UFA	50.98a	47.79b	51.15a	0.79	0.0116
SFA/UFA	0.93b	1.05a	0.92b	0.03	0.0110