Recommended fertilization and timing of nitrogen fertilization influences the morphogenesis, structural characteristics, and production efficiency of Mombaça grass

Paiva, Harry Sousa; Sousa, Sheila Vilarindo de; Conceição, Ellen Cristina de Araújo da; Santos, Antônio Clementino dos; Okumura, Ricardo Shigueru; Mezzomo, Rafael; Santos, Perlon Maia dos; Maciel, Raylon Pereira

doi:10.4025/actascianimsci.v45i1.60704

ABSTRACT.

This study aimed to evaluate whether different fertilization strategies influence the morphogenic, structural, and production characteristics of Megathyrsus maximus cv. Mombaça. The experimental design adopted was a randomized block design with a 4 × 3 factorial scheme having five replications. The treatments were as per the following fertilization recommendations: 5^th Approach Guide (5AP), Pará Guide (PG), Nutrient Replacement (RP), and the Michaelis and Menten adapted model (MM), applied for three days after application of the nitrogen (N) source following defoliation (days 0, 3, and 6). The interaction between factors affected the following variables: leaf appearance rate (LAR), leaf elongation rate (LER), and leaf senescence rate (LSR). The highest stem elongation rate (SER) was observed for the 5AP recommendation treatment with N application on day 0 (0.113 cm). The highest leaf area index (LAI; 5.33) and tiller population density (TPD; 421.5 tillers m^-2) were observed for the 5AP recommendation. The 5AP recommendation with N application on day 0 and on the sixth day after defoliation, and the MM recommendation with fertilization on day 0 showed the best LAR and LER, as well as a greater number of cycles and greater absolute values of leaf blade dry mass.

Keywords:
fertilization; pasture management; Megathyrsus maximus; urea

Introduction

One of the main reasons for the reduction in the productive potential of grasses in the Amazon region is inadequate nutritional management, which makes soil correction and fertilization necessary to meet the plants' nutritional requirements.

There are several recommendations for pasture fertilization, such as the guidance of correctives and fertilizers - the 5^th approach of Minas Gerais (Cantarutti, Alvarez, & Ribeiro, 1999Cantarutti, R. B., Alvarez, V. V. H., & Ribeiro, A. C. (1999). Pastagens. In A. C. Ribeiro, P. T. G. Guimarães, & V. V. H. Alvarez (Eds.), Recomendações para uso de corretivos e fertilizantes em Minas Gerais - 5ª aproximação (p. 332-341). Viçosa, MG: CFSEMG/UFV.) and the liming and fertilization guide of the state of Pará (Teixeira, Oliveira, & Veiga, 2007Teixeira, L. B., Oliveira, R. F., & Veiga, J. B. (2007). Recomendação de Adubação para Pastagens. In M. S. Cravo, I. J. M. Viégas, & E. C. Brasil (Orgs.), Recomendações de Adubação e Calagem para o Estado do Pará. Belém, PA: Embrapa - Amazônia Oriental.). Another model proposed by Lana et al. (2015Lana, R. P., Goes, R. H. T. B., Mancio, A. B., Fonseca, D. M., Moreira, L. M., & Tedeschi, L. O. (2015). Uso do modelo de Lineweaver-Burk de transformação de dados para explicar a resposta animal e vegetal ao nível variável de nutrientes. In R. P. Lana (Org.), Respostas Animais e Plantas aos Nutrientes (p. 27-38). Viçosa, MG: Editora UFV.) was evaluated using the Michaelis-Menten enzyme kinetic saturation model, the objective of which is to recommend levels in a more rational way. Another proposal is the replacement of nutrients extracted by plants during the production process (Brasil, Viégas, Silva, & Gato, 1999Brasil, E. C., Viégas, I. J. M., Silva, E. S. A., & Gato, R. (1999). Nutrição e adubação: conceitos e aplicações na formação de mudas de pimenta longa (p. 23). Belém, PA: EMBRAPA Amazônia Oriental.). These recommendations differ, especially in the amount of nitrogen (N) supplied, thus making it necessary to evaluate the responses of pastures to fertilization based on these recommendations for the region.

Tropical grass pastures intensively managed during the rainy season were fertilized with nitrogen after the animals were removed from the paddocks. However, the soil is highly susceptible to nitrogen losses (Gomide, Paciullo, Morenz, Costa, & Lanzoni, 2019Gomide, C. A., Paciullo, D. S., Morenz, M. J., Costa, I. A., & Lanzoni, C. L. (2019). Productive and morphophysiological responses of Panicum maximum Jacq. cv. BRS Zuri to timing and doses of nitrogen application and defoliation intensity.Grassland Science,65(2), 93-100. DOI: https://doi.org/10.1111/grs.12226
https://doi.org/https://doi.org/10.1111/... ), and alternatives are needed to improve nitrogen utilization by plants. Notably, after defoliation, there is a rapid decline in the amount of soluble carbohydrates in the roots as a consequence of the reduced photosynthetic rate and preferential allocation of carbon to the shoots of the grass, in order to restore the leaf area (Santos et al., 2011Santos, M. E. R., Fonseca, D. M. D., Braz, T. G. D. S., Silva, S. P. D., Gomes, V. M., & Silva, G. P. (2011). Características morfogênicas e estruturais de perfilhos de capim-braquiária em locais do pasto com alturas variáveis.Revista Brasileira de Zootecnia,40(3), 535-542. DOI: https://doi.org/10.1590/S1516-35982011000300010
https://doi.org/https://doi.org/10.1590/... ). Therefore, these factors should be considered when determining the ideal time for cover fertilization with nitrogen after defoliation. We hypothesized that there may be a relationship between fertilizer recommendations and the day of N application after defoliation, in terms of nitrogen utilization efficiency of the plant. The understanding of this relationship may guide the producers in choosing a fertilization management method that best suits their production system.

Therefore, the purpose of this study was to evaluate whether different fertilization recommendations and days of N fertilization influence the morphogenesis, structural characteristics, and production efficiency of the grass Megathyrsus maximus (syn. Panicum maximum) cv. Mombaça.

Material and methods

The study was conducted from December 20, 2018, to July 20, 2019, in the Forage Crops Sector of the Federal Rural University of Amazônia, Parauapebas Campus, Pará. The experimental area was located at latitude 06º04’16.4” south, longitude 49º08’8.3” west, and an altitude of 270 m. The soil in the area is classified as red-yellow Argisol (Santos et al., 2018Santos, H. G., Jacomine, P. K. T., Dos Anjos, L. H. C., De Oliveira, V. A., Lumbreras, J. F., Coelho, M. R., & Cunha, T. J. F. (2018).Sistema brasileiro de classificação de solos. Brasília, DF: Embrapa.). The climate of the region is classified as Aw-Tropical, with a dry season from May to October and a rainy season from November to April, according to Köppen. The average air temperature in the experimental period was 26.74ºC (with a maximum of 35.5+0.2ºC and a minimum of 20.7+0.2ºC) and the cumulative rainfall was 1,486.8 mm. For the chemical and physical characterization of the experimental area, soil analysis was performed at a depth of 0-20 cm (Table 1).

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Table 1. Chemical
and granulometric characteristics of the soil of the experimental area in the layer 0-20 cm deep.

Sowing of Megathyrsus maximus cv. Mombaça was performed in January (2018) in a semi-mechanized manner with a sprayer regulated for application of 15 kg ha^-1, using 4 kg of embedded-type seeds with a crop value (CV) of 80%.

The experiment was carried out using a randomized block design, with a 4 × 3 factorial scheme, including four fertilization recommendations (5^th Approach - 5AP; Nutrient Replacement - RP; Liming and Fertilization Guide of Pará State - PG; and Michaelis-Menten Model - MM), and there were three days of application of nitrogen fertilizer (N) after defoliation (N application after defoliation - Day 0; N application on the third day after defoliation - Day 3; and N application on the sixth day after defoliation - Day 6), with five replications, totaling 60 plots with an area of 9 m² (3 × 3) each, separated by 0.70-m wide corridors.

The recommendations and amounts of fertilizer expected to be used in the study for each fertilization strategy are shown in Table 2.

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Table 2. Nitrogen
(N), phosphorus pentoxide (P₂O₅) and potassium oxide (K₂O) values predicted for each fertilization strategy to be applied over one (1) crop year, with fertilizations occurring in the rainy season, comprising seven (7) cycles.

Fertilization with P (single superphosphate, 17% P₂O₅) and K (potassium chloride, 60% K₂O) was performed at the beginning of the rainy season, after the pasture was uniform. Urea (45% N) was used for nitrogen fertilization in split doses for seven applications (expected number of production cycles). The defoliation time was determined by considering the height for harvest and residue of 70 and 30 cm, respectively, according to Santos et al. (2021Santos, P. M., Maciel, R. P., Mezzomo, R., Santos, A. C., Faria, A. F. G., & Sousa, F. H. L. (2021). Recommendations of fertilization and defoliation of mombaça grass to Carajás - Pará Region: Efficiency and effects on soil. Revista Agri-Environmental Sciences, 7, 1-14. DOI: https://doi.org/10.36725/agries.v7i1.5349
https://doi.org/https://doi.org/10.36725... ).

The marked tiller technique was used (Davies, 1993Davies, A. (1993). Tissue turnover in the sward. In. A. Davies, R. D. Baker, S. A. Grant, & A. S. Laidlaw (Orgs.). Sward measurement handbook (p. 183-216). Hurley, UK: British Grassland Society.). Five tillers were identified per experimental unit five days after the uniformization cut, totaling 25 (twenty-five) tillers per treatment. The leaves of each tiller were evaluated weekly and marked after cutting (until the time of a new cut). Leaf blade lengths were measured and the leaves were classified as either expanding, expanded, senescent, or dead leaves. The stem length was measured from the ground to the ligule of the youngest fully expanded leaf.

The following variables were calculated and determined according to the methodology described by Alexandrino, Candido and Gomide (2011Alexandrino, E., Candido, M. J. D., & Gomide, J. A. (2011). Biomass flow and herbage net accumulation rate in Mombaca Grass under different heights. Revista Brasileira de Saúde e Produção Animal, 12, 59-71.): leaf appearance rate (LAR, cm of leaf tiller^-1 day^-1), leaf elongation rate (LER, cm of leaf tiller^-1 day^-1), stem elongation rate (SER, cm of pseudo stem tiller^-1 day^-1), leaf senescence rate (LSR, cm of leaf tiller^-1 day^-1), tiller population density (TPD, tillers m^-2) and leaf area index (LAI, m² m^-2).

The height of the pasture was continuously monitored; when it reached 70 cm, the forage was harvested using a rectangular frame of 0.6 m², leaving 30 cm of residue. The samples were weighed on a semi-analytical scale; thereafter, an aliquot was taken to determine the dry mass and another to separate the morphological components (i.e., leaf (leaf blades), pseudo-stem, and dead plant material). The samples were dried in a forced ventilation oven at 55°C for 72h to obtain the total forage dry mass (TFDM), leaf blade dry mass (LBDM), stem dry mass (SDM), and dead material dry mass (DMDM) according to the INCT-CA G 001/1 method described by Detmann et al. (2012Detmann, E., Souza, M. A., Valadares Filho, S. C., Queiroz, A. C., Berchielli, T. T., Saliba, E. O. S., & Azevedo, J. A. G. (2012). Métodos para análise de alimentos - INCT-Ciência Animal (p. 214). Visconde do Rio Branco, MG: Suprema.). The total yields of TFDM, LBDM, SDM, and DMDM were assessed in kg ha^-1.

The efficiency of Mombaça grass was expressed as a function of the leaf blade dry mass. The partial efficiency values were obtained by calculating the ratio of LBDM (t ha^-1) to the amount of fertilizer applied in kg (N, P, and K present in the treatments) (Santos & Fonseca, 2016Santos, M. E. R., & Fonseca, D. D. (2016). Aporte de nutrientes em pastagem tropical: uma necessidade. In M. E. R. Santos & D. M. Fonseca (Orgs.), Adubação de pastagens em sistemas de produção animal. Viçosa, MG: UFV.). Efficiency comprises the LBDM produced from the application of a given unit of fertilizer.

The values in reais necessary to produce one ton of LBDM were calculated as follows: [(total amount of reais spent on N + P + K in the treatment throughout the experimental period) / LBDM (t ha^-1)] and expressed in reais (R$ / t of LBDM). In order to obtain the average values in reais of kg of fertilizers (for subsequent use in the calculation above), a market survey was carried out in the main input stores of the city of Parauapebas, Pará State. At least three stores were consulted to determine the average values in reais of the fertilizers urea (R$ 3.30), single superphosphate (R$ 2.40) and potassium chloride (R$ 3.20).

The data were subjected to descriptive analysis, and the assumptions of normal distribution and homoscedasticity for the variables were verified. The results were subjected to analysis of variance, considering the fertilization recommendations, days of N application, and the interaction between these two factors as sources of variation, according to the following model:

Y _ijk = µ + b _{k +} E _i + D _j + (E.D) _ij + e _ijk ,

where Y _ijk is the value observed in the plot that received the factor E_i and D_j in block k; µ = general average; b _k = effect of the k^th block; E _i = effect of the i^th fertilization strategy on the response variable; D _j = effect of the j^th day of N application on the response variable; (E.D) _ij = effect of the interaction between fertilization recommendations × days of N application; and e _ijk = effect of the residual random error.

When significant effects were observed, the Tukey’s test was used, and the interactions were split. Agroestat online software was used (Maldonado Junior, 2019Maldonado Junior, W. (2019). AgroEstat Online. Retrieved from http://www.agroestat.com.br
http://www.agroestat.com.br... ). Differences were considered significant at p ≤ 0.05. The number of cycles and the number of days per cycle were not statistically analyzed because they did not contain replications; only nominal values were presented.

Results

With the application of nitrogen fertilizer on the same day after defoliation of Mombaça grass (Day 0), the recommendations 5AP, RP, PG, and MM showed five, four, three, and five production cycles, respectively. When the application of nitrogen fertilizer occurred on the third (Day 3) and sixth days (Day 6) after defoliation, five, three, three, and three cycles were recorded, respectively, for the previously mentioned recommendations (Table 3).

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Table 3
Total values of N, P₂O5 and K₂O in kg ha^-1, applied throughout the experimental period as a function of the number of production cycles and average cycle duration of Megathyrsus maximus (syn. Panicum maximum) cv. Mombaça grass.

Effects of the interaction between fertilization recommendations and timing of N fertilization on leaf appearance rate (LAR; p < 0.0001), leaf elongation rate (LER; p = 0.002), and leaf senescence rate (LSR; p = 0.001) are shown in Table 4.

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Table 4
Mean morphogenic variables of Megathyrsus maximus (syn. Panicum maximum) cv. Mombaça, under four fertilization recommendations in three periods (days) of N application.

The highest LAR values were recorded for the recommendations 5AP (0.091 cm leaf tiller^-1 day^-1) and MM (0.078 cm leaf tiller^-1 day^-1) when N fertilization was performed on the same day after defoliation. In contrast, the 5AP recommendation (0.093 cm leaf tiller^-1 day^-1) with N applied on the sixth day after cutting had no significant effect (p > 0.05) (Figure 1A).

N fertilization on the third day after defoliation, and the 5AP recommendation caused the highest LAR (0.071 cm leaf tiller^-1 day^-1), which was 60.6, 70.25, and 61.8% higher than that for RP, PG, and MM, respectively. On the sixth day, values for RP (0.064 cm leaf tiller^-1 day^-1) and MM (0.062 cm leaf tiller^-1 day^-1) did not show differences (Figure 1A).

When the N fertilization was performed on the day of defoliation, the recommendations 5AP (5.24 cm day^-1) and MM (4.79 cm day^-1) showed similar LER values (Figure 1B). The lowest LER values were observed for the RP and PG, which were 3.36 cm day^-1 and 2.52 cm day^-1, respectively (Table 4).

When N fertilization was performed on the third day after defoliation, the 5AP recommendation had values (4.12 cm day^-1) exceeding that for RP, PG, and MM by 68.7, 68.7, and 57.5%, respectively. When the fertilization was performed on the sixth day, LER values for recommendations 5AP (5.03 cm day^-1) and RP (3.96 cm day^-1) were similar to each other and higher than PG and MM values (Figure 1B).

There was no difference in LSR among N application treatments on the day of defoliation (Figure 1C). However, when N fertilization was performed on the third day after defoliation, LSR values for recommendations 5AP (0.95 cm tiller^-1 day^-1) and RP (0.68 cm tiller^-1 day^-1) did not differ from each other but were higher than MM (0.31 cm tiller^-1 day^-1). For N fertilization performed on the sixth day after defoliation, only RP (0.48 cm tiller^-1 day^-1) differed from MM (0.85 cm tiller^-1 day^-1) by 56.5%.

Figure 1
Mean LAR (A), LER (B), LSR (C), and yield of total forage dry mass - TFDM (D), total leaf blade dry mass - LBDM (E), total stem dry mass - SDM (F) and total dead material dry mass (G) in kg ha^-1 of Megathyrsus maximus (syn. Panicum maximum) cv. Mombaça grass under different fertilization recommendations in three periods (days) of N application after defoliation. Different uppercase letters indicate difference between fertilization recommendations on a given day of N application and different lowercase letters indicate difference between application days on a given fertilization recommendation.

Both fertilization recommendations (p = 0.006) and the timing of N fertilization affected SER (p = 0.003) (Table 3). When analyzing the effect of the recommendations, the highest SER was observed for 5AP (0.133 cm tiller^-1 day^-1), which was 32.5, 34.7, and 41.1% higher SER than RP, PG, and MM, respectively, and the latter three were similar in values. In addition, when nitrogen fertilization was performed on the day of defoliation, it promoted greater SER (0.113 cm tiller^-1 day^-1) compared to the fertilization performed on the sixth day (0.077 cm tiller^-1 day^-1) (Table 4).

Leaf area index (LAI) and tiller population density m-2 (TPD) were affected only by fertilization recommendations (p = 0.0001) (Table 3). The 5AP recommendation showed an average of 5.33 m² of leaf blades per m-2 of soil, which was superior by 28.9, 30.8, and 39.4% compared to MM (3.79), PR (3.69), and PG (3.23), respectively.

The highest tiller emission per m2 (421.5) was observed for the 5AP recommendation, which was superior to those of PG, PR, and MM by 49.7, 40.9, and 37.3%, respectively. The value for MM (264) was superior to that for PG (212).

There was an interactive effect between fertilization recommendations and the timing of nitrogen fertilization on TFDM (p = 0.0001), LBDM (p = 0.0001), DMDM (p = 0.0001), and SDM (p = 0.0008) (Table 5).

The highest TFDM (12,109 kg DM ha^-1) was recorded in case of the 5AP recommendation with nitrogen fertilization on the third day after defoliation (Figure 1D). When nitrogen fertilization was performed immediately after defoliation, the PG recommendation showed the lowest TFDM (7,473 kg DM ha^-1) among all recommendations. The other recommendations did not differ significantly (p > 0.05) from each other (11,538, 11,193, and 11,405 kg DM ha^-1 for 5AP, RP, and MM) (Figure 1D).

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Table 5
Mean yield variables of Megathyrsus maximus (syn. Panicum maximum) cv. Mombaça under four fertilization recommendations at three moments (days) of N application.

Similar to the TFDM, the LBDM showed higher yield (11,919 kg ha^-1) when nitrogen fertilization was performed on the third day after defoliation, in comparison to the fertilization immediately after defoliation in case of the 5AP fertilization recommendation (Figure 1E). PG showed the lowest LBDM (6,815.5 kg DM ha^-1) among all treatments when nitrogen fertilizer was applied immediately after defoliation. The other recommendations did not differ among themselves (p > 0.05).

The SDM value showed no change when nitrogen fertilization was applied immediately after defoliation, except for PG, which showed the lowest value. When the fertilization occurred on the third day, the 5AP recommendation produced the highest amount of stem mass (658.06 kg ha^-1), which was higher than RP (251.38 kg ha^-1) and MM (222.56 kg ha^-1). In addition, the recommended PG showed the least variation between the days of N application, with no effect on SDM as a function of fertilization timing. When the fertilization was performed on the sixth day after defoliation, the highest SDM was observed for the RP recommendation (550.7 kg ha^-1), which was higher than that for PG (255.1 kg ha^-1) and MM (215.7 kg ha^-1) by 46.3 and 39.2%, respectively (Figure 1F).

When the fertilization was performed right after defoliation, the RP recommendation produced the highest amount of DMDM (1,209.6 kg ha^-1), followed by MM (676.63 kg ha^-1), which was higher than PG (405.4 kg ha^-1) (Figure 1G). When performing fertilization on the third day after defoliation, the 5AP recommendation showed the greatest DMDM value (967.31 kg ha^-1), while the others PR, PG, and MM showed no significant differences. The application of 5AP recommendation with fertilization on the sixth day showed the greatest DMDM value (775.72 kg ha^-1), followed by that for PR (498.17 kg ha^-1). The PG treatment (293.6 kg ha^-1) had the lowest average of DMDM (Figure 1G).

In terms of the fertilizer-use efficiency of Mombaça grass (Table 6), the highest LBDM value was observed for the 5AP recommendation with fertilization on the third day after defoliation (5AP3), followed by MM with fertilization on day 0 (MM0), RP with fertilization on day 0 (RP0), and PG, which caused no differences in LBDM between the days of N application, presenting very close values for R$/ t of LBDM ha^-1 (R$ 188.17 193.36).

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Table 6
Use efficiency of N, P and K fertilizers supplied during the whole experimental period to the treatments, given in R$/ton of LBDM.

Discussion

The increase in N in the soil-plant system provided by the 5AP recommendation favored a high LAR after defoliation (Martuscello et al., 2005Martuscello, J. A., Fonseca, D. M., Nascimento Júnior, D., Santos, P. M., Ribeiro Junior, J. I., Cunha, D. N. F. V., & Moreira, L. M. (2005). Características morfogênicas e estruturais do capim-xaraés submetido à adubação nitrogenada e desfolhação. Revista Brasileira de Zootecnia, 34(5), 1475-1482. DOI: https://doi.org/10.1590/s1516-35982005000500007
https://doi.org/https://doi.org/10.1590/... ; Patês et al., 2007Patês, N. M. S., Pires, A. J. V., Silva, C. C. F., Santos, L. C., Carvalho, G. G. P., & Freire, M. A. L. (2007). Características morfogênicas e estruturais do capim-tanzânia submetido a doses de fósforo e nitrogênio. Revista Brasileira de Zootecnia, 36(6), 1736-1741. DOI: https://doi.org/10.1590/s1516-35982007000800005
https://doi.org/https://doi.org/10.1590/... ). The similarity of the results of RP and MM recommendations occurred due to a smaller difference in the N levels under both treatments, i.e., 85.7 and 78.6 kg, respectively. The MM recommendation showed LAR similar to that of 5AP on day 0.

LAR marks a centrally important response in morphogenesis, as it directly influences each of the structural components, and consequently, the leaf area index of the pasture (Lemaire & Chapman, 1996Lemaire, G., & Chapman, D. (1996). Tissue flows in grazed plant communities. In J. Hodgson, A. W. Illius, (Eds.), The ecology and management of grazing systems (p. 3-36). Wallingford: CAB International.; Alexandrino, Nascimento Júnior, Mosquim, Regazzi, & Rocha, 2004Alexandrino, E., Nascimento Júnior, D., Mosquim, P. R., Regazzi, A. J., & Rocha, F. C. (2004). Características morfogênicas e estruturais na rebrotação da Brachiaria brizantha cv. marandu submetida a três doses de nitrogênio. Revista Brasileira de Zootecnia, 33(6), 1372-1379. DOI: https://doi.org/10.1590/s1516-35982004000600003
https://doi.org/https://doi.org/10.1590/... ; Difante et al., 2011Difante, G. D. S., Nascimento Júnior, D. D., Silva, S. C. D., Euclides, V. P. B., Montagner, D. B., Silveira, M. C. T. D., & Pena, K. D. S. (2011). Características morfogênicas e estruturais do capim-marandu submetido a combinações de alturas e intervalos de corte.Revista Brasileira de Zootecnia, 40(5), 955-963. DOI: https://doi.org/10.1590/S1516-35982011000500003
https://doi.org/https://doi.org/10.1590/... ). According to Martuscello et al. (2015Martuscello, J. A., da Silva, L. P., da Cunha, D. N. F. V., Batista, A. C. S., Braz, T. G. S., & Ferreira, P. S. (2015). Adubação nitrogenada em capim-massai: Morfogênese e produção. Ciencia Animal Brasileira, 16, 1-13. DOI: https://doi.org/10.1590/1089-68916i118730
https://doi.org/https://doi.org/10.1590/... ), a higher LAR may be indicative of an increased number of leaves tiller^-1 and consequent gains in biomass yield.

N-deficient soils usually limit plant growth, with N and P required for the biosynthesis of abundant and essential biomolecules, such as proteins and nucleic acids, respectively (Rajasekar, Nandhini, Swaminathan, & Balakrishnan, 2017Rajasekar, M., Nandhini, D. U., Swaminathan, V., & Balakrishnan, K. (2017). A review on role of macro nutrients on production and quality of vegetables.International Journal Chemical Science, 5(3), 304-309.). The PG recommendation had the lowest N concentration per application, thus causing the lowest LAR, which corroborates the previous statement that N increment increases LAR in forage plants. The P content of PG, which was 80 kg ha^-1 of P₂O₅, was the highest among the treatments. However, this was not a decisive factor in the increase in LAR, and probably, the low N availability limited the use of P by the plant.

Evaluating the application of a fixed level of 90 kg N ha^-1 and 60 kg K₂O ha^-1 and varying only the levels of P₂O₅ (0, 30, 60, 90, and 120 kg ha^-1) in Megathyrsus maximus (syn. Panicum maximum) cv. Mombaça, Costa et al. (2017Costa, N. D. L., Jank, L., Magalhães, J. A., Fogaca, F. D. S., Rodrigues, A. N. A., & Santos, F. D. S. (2017). Acúmulo de forragem e morfogênese de Megathyrsus maximus cv. Mombaça sob níveis de fósforo.Embrapa Roraima-Artigo em periódico indexado (ALICE), 11(11). DOI: http://dx.doi.org/10.22256/PUBVET.V11N11.1163-1168
https://doi.org/http://dx.doi.org/10.222... ) reported a quadratic response for LAR, with a maximum point of 0.109 leaf day^-1 with the application of 60 kg P₂O₅. These values were close to those obtained in the present study for the 5AP recommendation when N was applied on days 0 and 6. We also observed the relevance of the association of N with P for a better response of forage plants.

Regarding the leaf elongation rate (LER), higher levels of N supplied by the 5AP recommendation caused the plant to present the most favorable moment for fertilizer application on the day of defoliation. It is possible that on the third day after cutting the plant, when N fertilizer was applied, it could respond physiologically to the stress of defoliation. For this reason, N fertilization on the third day for the 5AP recommendation led to reduced LER compared with that on day 0.

In the present study, the greatest stress caused to the plant did not seem to have been on the day of defoliation because the MM recommendation with N fertilization on the day of defoliation showed LER similar to that presented by the treatments of the 5AP recommendation. In fact, LER is an important measure in the analysis of plant tissue flow and has a positive relationship with forage yield, promoting greater accumulation of dry matter due to the increased proportion of leaves and photosynthetically active areas (Martuscello et al., 2006Martuscello, J. A., Fonseca, D. M. D., Nascimento Júnior, D. D., Santos, P. M., Cunha, D. D. N. F. V. D., & Moreira, L. D. M. (2006). Características morfogênicas e estruturais de capim-massai submetido a adubação nitrogenada e desfolhação.Revista Brasileira de Zootecnia, 35(3), 665-671. DOI: https://doi.org/10.1590/S1516-35982006000300006
https://doi.org/https://doi.org/10.1590/... ; Paciullo et al., 2017Paciullo, D. S. C., Gomide, C. A. M., Castro, C. R. T., Maurício, R. M., Fernandes, P. B., & Morenz, M. J. F. (2017). Morphogenesis, biomass and nutritive value of Panicum maximum under different shade levels and fertilizer nitrogen rates. Grass and Forage Science, 72(3), 590-600. DOI: https://doi.org/10.1111/gfs.12264
https://doi.org/https://doi.org/10.1111/... ).

According to Marques et al. (2016Marques, M. F., Romualdo, L. M., Martinez, J. F., Lima, C. G., Lunardi, L. J., Luz, P. H. C., & Herling, V. R. (2016). Momento de aplicação do nitrogênio e algumas variáveis estruturais e bromatológicas do capim-massai. Arquivo Brasileiro de Medicina Veterinaria e Zootecnia, 68(3), 776-784. DOI: https://doi.org/10.1590/1678-4162-8500
https://doi.org/https://doi.org/10.1590/... ), N fertilization has a direct and marked effect on the photosynthesizing leaf area as a consequence of the increase in the LER. However, it is worth mentioning that the 5AP recommendation provided at the beginning of the evaluation was 70 kg ha^-1 of P₂O₅, and the MM recommendation provided only 10 kg of P₂O₅ ha^-1, which shows that the participation of P in the morphogenic responses was less evident in this study.

The lower LER observed for 5AP, RP, and MM recommendations on the third day after defoliation may have occurred because of the cut, which would have stimulated the root metabolism of the plant to translocate photoassimilates to the shoot to recover the leaf area that is responsible for photosynthesis. At this moment, the plant would have a lower capacity to absorb nutrients, such as N. However, this behavior was not observed for the PG recommendation, possibly due to its low N level.

A higher SER may be a response to the higher level of N provided by the 5AP recommendation. Braz et al. (2011Braz, T. G. D. S., Fonseca, D. M. D., Freitas, F. P. D., Martuscello, J. A., Santos, M. E. R., Santos, M. V., & Pereira, V. V. (2011). Morphogenesis of Tanzania guinea grass under nitrogen doses and plant densities.Revista Brasileira de Zootecnia, 40(7), 1420-1427. DOI: https://doi.org/10.1590/S1516-35982011000700004
https://doi.org/https://doi.org/10.1590/... ) and Iwamoto et al. (2015Iwamoto, B. S., Cecatto, U., Ribeiro, O. L., Mari, G. C., Peluso, E. P., & Lourenço, D. A. L. (2015). Características morfogênicas do capim-Tanzânia fertilizado ou não com nitrogênio nas estações do ano. Bioscience Journal, 31, 181-193. DOI: https://doi.org/10.14393/bj-v31n1a2015-18077
https://doi.org/https://doi.org/10.14393... ) also observed this behavior when evaluating Megathyrsus maximus cv. Tanzania was subjected to higher levels of N. Higher SER can also be caused by the shading of the upper leaves over the leaves at the plant's base, according to Silva and Nascimento Junior (2007Silva, S. C., & Nascimento Júnior, D. (2007). Avanços na pesquisa com plantas forrageiras tropicais em pastagens: características morfofisiológicas e manejo do pastejo. Revista Brasileira de Zootecnia, 36(suppl), 122-138. DOI: https://doi.org/10.1590/s1516-35982007001000014
https://doi.org/https://doi.org/10.1590/... ). Although each forage species has its own genetic programming, SER can be intensified with increased competition for light. Therefore, the results of LAI and TPD obtained in this study may explain the higher SER in the 5AP recommendation, as these variables were higher in this recommendation.

Pasture N fertilization has a positive effect on leaf blade average length (LBAL) (Pereira et al., 2011Pereira, V. V., Fonseca, D. M., Martuscello, J. A., Braz, T. G. S., Santos, M. V., & Cecon, P. R. (2011). Características morfogênicas e estruturais de capim-mombaça em três densidades de cultivo adubado com nitrogênio. Revista Brasileira de Zootecnia, 40(12), 2681-2689. DOI: https://doi.org/10.1590/s1516-35982011001200010
https://doi.org/https://doi.org/10.1590/... ), because this nutrient significantly increases LER compared to the stimulus by LAR (Martuscello et al., 2006Martuscello, J. A., Fonseca, D. M. D., Nascimento Júnior, D. D., Santos, P. M., Cunha, D. D. N. F. V. D., & Moreira, L. D. M. (2006). Características morfogênicas e estruturais de capim-massai submetido a adubação nitrogenada e desfolhação.Revista Brasileira de Zootecnia, 35(3), 665-671. DOI: https://doi.org/10.1590/S1516-35982006000300006
https://doi.org/https://doi.org/10.1590/... ; Premazzi, Monteiro, & de Oliveira, 2011Premazzi, L. M., Monteiro, F. A., & de Oliveira, R. F. (2011). Crescimento de folhas do capim-bermuda tifton 85 submetido à adubação nitrogenada após o corte. Revista Brasileira de Zootecnia, 40(3), 518-526. DOI: https://doi.org/10.1590/S1516-35982011000300008
https://doi.org/https://doi.org/10.1590/... ). However, according to Volaire, Barkaoui, and Norton (2014Volaire, F., Barkaoui, K., & Norton, M. (2014). Designing resilient and sustainable grasslands for a drier future: Adaptive strategies, functional traits and biotic interactions. European Journal of Agronomy, 52, 81-89. DOI: https://doi.org/10.1016/j.eja.2013.10.002
https://doi.org/https://doi.org/10.1016/... ), final leaf blade length is a plastic trait that responds to defoliation intensity. Therefore, it is possible that no differences in LBAL were found, since all treatments had the same residue height (30 cm).

Studies on tropical forages, especially those with Megathyrsus maximus (syn. Panicum maximum) reported the influence of higher N availability on increased LSR (Iwamoto et al., 2015Iwamoto, B. S., Cecatto, U., Ribeiro, O. L., Mari, G. C., Peluso, E. P., & Lourenço, D. A. L. (2015). Características morfogênicas do capim-Tanzânia fertilizado ou não com nitrogênio nas estações do ano. Bioscience Journal, 31, 181-193. DOI: https://doi.org/10.14393/bj-v31n1a2015-18077
https://doi.org/https://doi.org/10.14393... ; Martuscello et al., 2015Martuscello, J. A., da Silva, L. P., da Cunha, D. N. F. V., Batista, A. C. S., Braz, T. G. S., & Ferreira, P. S. (2015). Adubação nitrogenada em capim-massai: Morfogênese e produção. Ciencia Animal Brasileira, 16, 1-13. DOI: https://doi.org/10.1590/1089-68916i118730
https://doi.org/https://doi.org/10.1590/... ; Santos & Fonseca, 2016Santos, M. E. R., & Fonseca, D. D. (2016). Aporte de nutrientes em pastagem tropical: uma necessidade. In M. E. R. Santos & D. M. Fonseca (Orgs.), Adubação de pastagens em sistemas de produção animal. Viçosa, MG: UFV.; Martuscello et al., 2019Martuscello, J. A., Rios, J. F., Ferreira, M. R., Assis, J. A., Braz, T. G. S., & Cunha, D. N. F. V. (2019). Produção e morfogênese de capim BRS Tamani sob diferentes doses de nitrogênio e intensidades de desfolhação. Boletim de Indústria Animal, 76, 1-10. DOI: https://doi.org/10.17523/bia.2019.v76.e1441
https://doi.org/https://doi.org/10.17523... ). However, this response was not observed in the present study.

The emission of tillers was stimulated by the use of increased levels of N in the 5AP recommendation, which suggests that the timing of N fertilization up to the sixth day after defoliation does not influence tillering like the amounts of N and P available to the pasture do. The increase in tillering is closely related to N fertilization, as it is linked to an increase in cell recycling, with the appearance and growth of tissues, including basilar and axillary buds, which are precursors of tillers (Martuscello et al., 2015Martuscello, J. A., da Silva, L. P., da Cunha, D. N. F. V., Batista, A. C. S., Braz, T. G. S., & Ferreira, P. S. (2015). Adubação nitrogenada em capim-massai: Morfogênese e produção. Ciencia Animal Brasileira, 16, 1-13. DOI: https://doi.org/10.1590/1089-68916i118730
https://doi.org/https://doi.org/10.1590/... ). Each time a new leaf is formed, an axillary bud also forms, which can develop into a new tiller (Santos & Fonseca, 2016Santos, M. E. R., & Fonseca, D. D. (2016). Aporte de nutrientes em pastagem tropical: uma necessidade. In M. E. R. Santos & D. M. Fonseca (Orgs.), Adubação de pastagens em sistemas de produção animal. Viçosa, MG: UFV.). The 5AP recommendation, with a total of 214.3 kg of N ha^-1, produced the most leaf blades, and consequently a greater number of axillary buds, which explains the higher tiller emission.

LAI showed a similar behavior, probably due to greater tillering. The isolated effect of the recommendations resulted in a greater LAI in 5AP, possibly due to the greater level of N applied to the plants. The greater leaf area shows evidence of the promoting effect of cell division influenced by N, which stimulates an increase in the production of new cells, in the rates of leaf appearance and elongation (Martuscello et al., 2005Martuscello, J. A., Fonseca, D. M., Nascimento Júnior, D., Santos, P. M., Ribeiro Junior, J. I., Cunha, D. N. F. V., & Moreira, L. M. (2005). Características morfogênicas e estruturais do capim-xaraés submetido à adubação nitrogenada e desfolhação. Revista Brasileira de Zootecnia, 34(5), 1475-1482. DOI: https://doi.org/10.1590/s1516-35982005000500007
https://doi.org/https://doi.org/10.1590/... ). Notably, the level of 70 kg of P₂O₅ ha^-1 (30.57 kg P ha^-1) preconized by the 5AP recommendation, associated with the N supplied (214.3 kg ha^-1), may have promoted better utilization by the plants. Such factors in addition to higher tillering may translate into an increase in the LAI.

A greater TPD associated with a greater LAI provides faster plant recovery after defoliation. It is possible that the residue of defoliation has a greater residual leaf blade area, which results in better conditions for regrowth in shorter periods.

From the information obtained in this study, it was observed that the level of N was the most influential for the variations in LAR and LER for the 5AP, RP, and MM recommendations. This caused the plants to present the greatest responses for these recommendations, with similar behavior when N fertilization was performed on days 0 and 6. In Figures 1A and 1B, it is observed that the fertilization performed on the third day after defoliation promoted a reduction in the values of LAR and LER. This because on day 0, the plant had not yet physiologically responded to the stress of defoliation.

The reduction in LAR on day 3 may be related to the plant’s response to defoliation, and on day 6, there may have been plant recovery from harvest stress, as on that day the plant presented the largest leaf area. Santos, Thornton, and Corsi (2012Santos, P. M., Thornton, B., & Corsi, M. (2012). Adaptation of the C4 grass Panicum maximum to defoliation is related to plasticity of N uptake, mobilisation and allocation patterns. Scientia Agricola, 69(5), 293-299. DOI: https://doi.org/10.1590/S0103-90162012000500002
https://doi.org/https://doi.org/10.1590/... ) stated that defoliation reduces root activity in Panicum maximum, and according to the authors, the species is mainly dependent on N uptake by the root to ensure growth after defoliation.

The PG recommendation was the only one that did not cause differences in LAR and LER between fertilization stages. Despite the 80 kg of P₂O₅ made available, owing to the low level of N recommended by the guide, its effect on the forage may have been innocuous, being indifferent to the day of fertilization.

Evaluation of Megathyrsus maximus cv. Faria et al. (2019Faria, D. A., Avelino, A. C. D., Cabral, C. E. A., Abreu, J. G., Barros, L. V., Cabral, C. H. A., ... Assis, L. M. B. (2019). Investigating the optimal day for nitrogen fertilization on Piatã palisadegrass and Quênia guineagrass after defoliation. Journal of Experimental Agriculture International, 34(6), 1-11. DOI: https://doi.org/10.9734/JEAI/2019/v34i530192
https://doi.org/https://doi.org/10.9734/... ) tested different moments of N fertilization after defoliation and found greater accumulation of root DM when fertilization occurred on the sixth day after defoliation. Although the study was carried out in a greenhouse, this information may explain, in part, the better performance of LAR and LER in the present study for the 5AP, RP, and MM recommendations on the sixth day in comparison to the fertilization performed on the third day after defoliation.

Another factor that should be noted was the number of cycles during the evaluation period. Only the 5AP recommendation (at the three N fertilization moments) and MM recommendation (fertilization on day 0) provided five cycles. Proper pasture management can be obtained by the number of more frequent defoliation cycles (Zanine et al., 2013Zanine, A. M., Nascimento Júnior, D., Sousa, B. M. L., Silveira, M. C. T., Silva, W. L., & Santos, M. E. R. (2013). Tillering dynamics in Guinea grass pastures subjected to management strategies under rotational grazing. Revista Brasileira de Zootecnia, 42(3), 155-161. DOI: https://doi.org/10.1590/S1516-35982013000300002
https://doi.org/https://doi.org/10.1590/... ), as SER and LSR are affected by the frequency of defoliation, in which a higher frequency implies lower rates (Zanine et al., 2018Zanine, A. M., Nascimento Júnior, D., Da Silva, W. L., Sousa, B. M. D. L., Ferreira, D. D. J., Da Silveira, M. C. T., ... Santos, M. E. R. (2018). Morphogenetic and Structural Characteristics of Guinea Grass Pastures under Rotational Stocking Strategies. Experimental Agriculture, 54(2), 243-256. DOI: https://doi.org/10.1017/S0014479716000223
https://doi.org/https://doi.org/10.1017/... ), which depreciates the nutritive value and decreases animal performance. Therefore, the MM recommendation with fertilization on the day of defoliation showed a lower stem elongation rate, which may result in forage of better quality.

Similar values were observed in treatments 5AP3 and 5AP6 for TFDM, possibly due to the higher amount of N applied after defoliation. However, one should evaluate the importance of P, which together with N are necessary for the biosynthesis of abundant and essential biomolecules, such as proteins and nucleic acids, respectively (Rajasekar et al., 2017Rajasekar, M., Nandhini, D. U., Swaminathan, V., & Balakrishnan, K. (2017). A review on role of macro nutrients on production and quality of vegetables.International Journal Chemical Science, 5(3), 304-309.).

By acting as a source of photoassimilates for new leaf emissions, the plant probably limited the utilization of the maximum N supplied. Defoliation affects the specific N uptake by the root, and therefore, the potential for uptake to supply growing leaves (Thornton & Millard, 1997Thornton, B., & Millard, P. (1997). Increased defoliation frequency depletes remobilization of nitrogen for leaf growth in grasses. Annals of Botany, 80, 89-95. DOI: https://doi.org/10.1006/anbo.1997.0416
https://doi.org/https://doi.org/10.1006/... ). However, in the present study, it was not possible to determine the exact time that this occurred, but it is likely that it occurred between the day of defoliation and the third day, which explains the higher TFDM in the 5AP recommendation with N fertilization on days three and six after defoliation, when the plant had sufficient leaf area to alter the source-drain relationship and allow greater N uptake by the root.

When the RP and MM recommendations were analyzed, the best responses were obtained when the N source was applied on day 0. It is possible that N helped the plant re-establish itself soon after defoliation.

The PG recommendation was the only one in which the timing of N fertilization did not influence the dry matter yield (TFDM). The low amount of N supplied was the limiting factor despite supplying a good amount of phosphorus (P). This mineral, in turn, in the amounts provided by the recommendations, did not limit plant growth.

The average proportion of leaves in the morphological composition for all treatments was 88.7%. The 5AP recommendation, regardless of the timing of N fertilization, presented the highest LBDM. Therefore, this result shows that when this recommendation is adopted, it is possible to work with greater flexibility in the application of N fertilizer, but the efficiency of use of the inputs by the plant must be taken into consideration.

Fertilization with N is related to greater protein production because it provides more N for protein synthesis and enhances the development of leaf blades (Alexandrino et al., 2004Alexandrino, E., Nascimento Júnior, D., Mosquim, P. R., Regazzi, A. J., & Rocha, F. C. (2004). Características morfogênicas e estruturais na rebrotação da Brachiaria brizantha cv. marandu submetida a três doses de nitrogênio. Revista Brasileira de Zootecnia, 33(6), 1372-1379. DOI: https://doi.org/10.1590/s1516-35982004000600003
https://doi.org/https://doi.org/10.1590/... ). Moreover, the use of higher levels of N, as in the case of the 5AP recommendation, stimulates greater tiller emission than the other recommendations (RP, PG, and MM). This also explains the higher LBDM yield in treatments with the 5AP recommendations.

From the results presented in this study, it is evident that using the RP and MM recommendations, the timing of fertilization has a more intense influence on the production of leaf blades. The greatest elasticities in production were observed when the N level was lower, which was noticeable for the RP and MM recommendations with fertilization on day 0, with total levels of 21.42 and 15.72 kg of N ha^-1 cycle^-1, and there was greater productivity for fertilizations on the third or sixth day after defoliation.

It is possible that physiological stress after defoliation was triggered after day 0, unlike in plants treated with 5AP. Therefore, it can be suggested that for the recommendations that used lower levels of N (RP and MM), the plants did not immediately decrease the uptake of nutrients from the soil, therefore, even in smaller amounts, the N applied on day 0 stimulated the plants to expand their leaf area and recover more quickly from a possible deficit of assimilates.

In general, SDM was reduced in this study. The average of the treatments was 4.5% of the total harvested dry mass, which can be seen as a positive factor because the stem has a lower nutritional value than the leaf blade. Stem elongation occurs when the LAI is above the critical level; therefore, it is a plant strategy to intercept light of high quality and quantity in the lower leaves (Alexandrino, Gomide, & Gomide, 2005Alexandrino, E., Gomide, J. A., & Gomide, C. A. D. M. (2005). Crescimento e desenvolvimento do dossel de Panicum maximum cv. Mombaça.Revista Brasileira de Zootecnia, 34, 2164-2173. DOI: https://doi.org/10.1590/S1516-35982005000700002
https://doi.org/https://doi.org/10.1590/... ). It is likely that in this study, the plants did not reach the critical LAI because of the lower proportion of stems in the material harvested up to 30 cm from the ground level.

SDM yield may be correlated with higher N input to the soil, which stimulates a higher number of production cycles. Therefore, in the treatments with five production cycles, the three fertilization recommendations with 5AP and MM on day 0 and RP on day 0 with four cycles showed higher stem yields. The same pattern was observed for dry matter and leaf blade yield.

Regarding the amount of DMDM, the literature explains that higher levels of fertilizers, especially nitrogen, increase tillering, parallel leaf size, and LAI (Martuscello et al., 2005Martuscello, J. A., Fonseca, D. M., Nascimento Júnior, D., Santos, P. M., Ribeiro Junior, J. I., Cunha, D. N. F. V., & Moreira, L. M. (2005). Características morfogênicas e estruturais do capim-xaraés submetido à adubação nitrogenada e desfolhação. Revista Brasileira de Zootecnia, 34(5), 1475-1482. DOI: https://doi.org/10.1590/s1516-35982005000500007
https://doi.org/https://doi.org/10.1590/... ). This response to nitrogen fertilization causes the plant to present greater shading of the forage canopy, and the older leaves and those at the base of the stem tend to decrease the photosynthetic rate and begin senescence, increasing the amount of dead material (Santos et al., 2011Santos, M. E. R., Fonseca, D. M. D., Braz, T. G. D. S., Silva, S. P. D., Gomes, V. M., & Silva, G. P. (2011). Características morfogênicas e estruturais de perfilhos de capim-braquiária em locais do pasto com alturas variáveis.Revista Brasileira de Zootecnia,40(3), 535-542. DOI: https://doi.org/10.1590/S1516-35982011000300010
https://doi.org/https://doi.org/10.1590/... ).

The treatments that adopted the 5AP recommendation obtained the highest DMDM values, which occurred with N fertilization on the third and sixth days after defoliation. However, with fertilization immediately after cutting (day 0), the 5AP recommendation, which was expected to yield similar results to those obtained on the third and sixth days due to good forage mass yield and higher LAI, showed one of the lowest values of DMDM followed by PG and MM. In fact, it is likely that although the LAI value was higher than the other fertilization recommendations, it did not reach a value close to the critical LAI due to the low DMDM.

Based on the agronomic variables, it was observed that the 5AP recommendations at the three periods of N application, and MM and RP with N application on the day of defoliation, showed the highest TFDM. However, MM, from the point of view of fertilizer use efficiency and saving of financial resources, exceeded 5AP, as the cost of fertilizers to produce one ton of DM was 3.56 times lower (Table 5).

Conclusion

To obtain a greater number of production cycles and higher absolute values of leaf blade dry mass (LBDM), the 5AP recommendation should be adopted with N application on the same day and/or on the sixth day after defoliation and the MM recommendation with N application on the same day of defoliation. In contrast, the best LBDM production efficiency of LBDM is obtained with the MM recommendation with N fertilization on the same day of defoliation. It is also worth mentioning that different recommendations present diverse results and should be applied according to the reality of each production system.

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Publication Dates

Publication in this collection
09 Oct 2023
Date of issue
2023

History

Received
27 Aug 2021
Accepted
29 Apr 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[33] Santos, H. G., Jacomine, P. K. T., Dos Anjos, L. H. C., De Oliveira, V. A., Lumbreras, J. F., Coelho, M. R., & Cunha, T. J. F. (2018).Sistema brasileiro de classificação de solos Brasília, DF: Embrapa.

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[40] Thornton, B., & Millard, P. (1997). Increased defoliation frequency depletes remobilization of nitrogen for leaf growth in grasses. Annals of Botany, 80, 89-95. DOI: https://doi.org/10.1006/anbo.1997.0416
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[41] Volaire, F., Barkaoui, K., & Norton, M. (2014). Designing resilient and sustainable grasslands for a drier future: Adaptive strategies, functional traits and biotic interactions. European Journal of Agronomy, 52, 81-89. DOI: https://doi.org/10.1016/j.eja.2013.10.002
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[42] Zanine, A. M., Nascimento Júnior, D., Da Silva, W. L., Sousa, B. M. D. L., Ferreira, D. D. J., Da Silveira, M. C. T., ... Santos, M. E. R. (2018). Morphogenetic and Structural Characteristics of Guinea Grass Pastures under Rotational Stocking Strategies. Experimental Agriculture, 54(2), 243-256. DOI: https://doi.org/10.1017/S0014479716000223
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[43] Zanine, A. M., Nascimento Júnior, D., Sousa, B. M. L., Silveira, M. C. T., Silva, W. L., & Santos, M. E. R. (2013). Tillering dynamics in Guinea grass pastures subjected to management strategies under rotational grazing. Revista Brasileira de Zootecnia, 42(3), 155-161. DOI: https://doi.org/10.1590/S1516-35982013000300002
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pH	P(Melich)	K	Ca²⁺	Mg²⁺	Al	H+Al	V%	CEC	OM	Clay	Silt	Sand
(CaCl₂)	mg dm^-3		----------------cmol_c dm^-3---------------						g dm^-3	dag.kg^-1
4.6	0.8	121.3	2.2	0.7	0.2	2.2	59.33	5.41	21.0	310	80	610

	Fertilization Recommendations (kg ha^-1)
	5AP	RP	PG	MM
	Day 0
kg ha^-1 of N, P₂O₅ and K₂O	214.3- 70- 0	85.7- 16- 60	25.7- 80- 0	78.6- 10 -0
Number of Cycles	5	4	3	5
Interval between cycles (days)	27	30	43	31
	Day 3
kg ha^-1 of N, P₂O₅ and K₂O	214.3- 70- 0	64.3- 16- 60	25.7- 80- 0	47.1- 10- 0
Number of Cycles	5	3	3	3
Interval between cycles (days)	31	42	35	44
	Day 6
kg ha^-1 of N, P₂O₅ and K₂O	214.3- 70- 0	64.3- 16- 60	25.7- 80- 0	47.1- 10- 0
Number of Cycles	5	3	3	3
Interval between cycles (days)	27	41	42	42

Variables	Recommendations				Day of N application			SEM	P Value
Variables	5AP	RP	PG	MM	0	3	6		Rec.	Days	R x D
LAR	0.08	0.06	0.05	0.06	0.07	0.05	0.07	0.001	<0.0001	<0.0001	<0.0001
LER	4.79	3.38	2.71	3.50	3.97	3.03	3.78	0.10	<0.0001	0.0002	0.0020
SER	0.13a	0.09b	0.09b	0.08b	0.11A	0.10AB	0.08B	0.16	<0.0060	<0.003	0.0620
LSR	0.88	0.62	0.55	0.70	0.73	0.63	0.67	0.04	0.0020	0.1030	0.0010
LAI	5.33a	3.69b	3.23b	3.79b	4.06	4.13	3.84	0.02	0.0001	0.4340	0.1600
TPD	421.5a	249.1bc	212.0c	264.4b	292.5	279.4	288.4	0.16	0.0001	0.7780	0.1690

Variables	Recommendations				Day of N application			SEM	P Value
Variables	5AP	RP	PG	MM	0	3	6		Rec.	Days	R x D
TFDM	12,607.95	8,793.86	7,598.96	9,084.66	10,402.23	9,304.59	8,857.26	5.46	0.0001	0.0001	0.0001
LBDM	11,197.00	7,758.70	6,902.20	8,231.00	9,350.90	8,208.90	8,007.00	0.01	0.0001	0.0001	0.0001
DMDM	726.44	762.72	402.14	508.23	681.97	645.81	471.87	0.37	0.0001	0.0002	0.0001
SDM	587.3	496.89	294.59	345.41	537.71	378.38	377.06	2.22	0.0001	0.0042	0.0008

	Fertilizers cost (R$ t^-1 of LBDM ha^-1)
	Urea	S.S	KCl	NPK Cost	LBDM Yield	Efficiency
Treatments	45%	17%	60%	(R$)	(t ha^-1)	(R$/ t LBDM)
5AP0	476.22	411.76	0	R$2,559.77	10.48	R$244.25
5AP3	476.22	411.76	0	R$2,559.77	11.452	R$223.52
5AP6	476.22	411.76	0	R$2,559.77	11.15	R$229.58
RP0	190.44	94.12	100	R$1,174.35	9.784	R$120.03
RP3	142.89	94.12	100	R$1,017.42	6.5899	R$154.39
RP6	142.89	94.12	100	R$1,017.42	6.6422	R$153.17
PG0	57.11	470.59	0	R$1,317.88	6.8155	R$193.36
PG3	57.11	470.59	0	R$1,317.88	7.0036	R$188.17
PG6	57.11	470.59	0	R$1,317.88	6.8571	R$192.19
MM0	174.67	58.82	0	R$717.58	10.023	R$71.59
MM3	104.67	58.82	0	R$486.58	7.292	R$66.73
MM6	104.67	58.82	0	R$486.58	7.2705	R$66.92

Recommendations		Fertilizer (kg ha^-¹ year^-¹)
Recommendations		N	P₂O₅	K₂O
5^th Approach Guide (5AP)	According to the recommendation for production system of medium technological level (Cantarutti et al., 1999Cantarutti, R. B., Alvarez, V. V. H., & Ribeiro, A. C. (1999). Pastagens. In A. C. Ribeiro, P. T. G. Guimarães, & V. V. H. Alvarez (Eds.), Recomendações para uso de corretivos e fertilizantes em Minas Gerais - 5ª aproximação (p. 332-341). Viçosa, MG: CFSEMG/UFV.).	300	70	-
Nutrient Replacement (RP)	According to the equation adapted from Brasil et al. (1999Brasil, E. C., Viégas, I. J. M., Silva, E. S. A., & Gato, R. (1999). Nutrição e adubação: conceitos e aplicações na formação de mudas de pimenta longa (p. 23). Belém, PA: EMBRAPA Amazônia Oriental.), where: “Fertilization = (Requirement + Factor) - supply”, with the requirement being calculated according to Castagnara et al. (2014Castagnara, D. D., Mesquita, E. E., Neres, M. A., Oliveira, P. S. R., Zoz, T., & Zoz, A. (2014). Morphogenesis and production of Tanzânia, Mombaça and Mulato grasses under nitrogen fertilization. Bioscience Journal, 30(3 Suppl. 1), 45-54.), Sousa et al. (2010Sousa, R. S., Pires, A. J. V., Carvalho, G. G. P., Silva, F. F., Magalhães, A. F., & Veloso, C. M. (2010). Composição química de capim-tanzânia adubado com nitrogênio e fósforo. Revista Brasileira de Zootecnia, 39(6), 1200-1205. DOI: https://doi.org/10.1590/S1516-35982010000600006 https://doi.org/https://doi.org/10.1590/... ) and Freitas et al. (2011Freitas, K. R., Rosa, B., Nascimento, J. L., Borges, R. T., Barbosa, M. M., & Santos, D. D. C. (2011). Composição química do Capim-Mombaça (Panicum maximum Jacq.) submetido à adubação orgânica e mineral. Ciência Animal Brasileira, 12(3). DOI: https://doi.org/10.5216/cab.v12i3.3309 https://doi.org/https://doi.org/10.5216/... ); the factor according to Oliveira, Favaretto, Roloff and Fernandes (2010Oliveira, M. F. M., Favaretto, N., Roloff, G., & Fernandes, C. V. S. (2010). Estimativa do potencial de perda de fósforo através da metodologia “P Index.” Revista Brasileira de Engenharia Agrícola e Ambiental, 14(3), 267-273. DOI: https://doi.org/10.1590/s1415-43662010000300005 https://doi.org/https://doi.org/10.1590/... ); and the supply according to Braz et al. (2002Braz, S. P., Do Nascimento, D., Cantarutti, R. B., Regazzi, A. J., Martins, C. E., Da Fonseca, D. M., & Barbosa, R. A. (2002). Aspectos quantitativos do processo de reciclagem de nutrientes pelas fezes de bovinos sob pastejo em pastagem de Brachiaria decumbens na Zona da Mata de Minas Gerais. Revista Brasileira de Zootecnia, 31(2 Suppl.), 858-865. DOI: https://doi.org/10.1590/s1516-35982002000400008 https://doi.org/https://doi.org/10.1590/... ).	150	16	60
Pará Guide (PG)	According to the recommendation for semi-intensive and intensive rotational grazing systems (Teixeira et al., 2007Teixeira, L. B., Oliveira, R. F., & Veiga, J. B. (2007). Recomendação de Adubação para Pastagens. In M. S. Cravo, I. J. M. Viégas, & E. C. Brasil (Orgs.), Recomendações de Adubação e Calagem para o Estado do Pará. Belém, PA: Embrapa - Amazônia Oriental.).	60	80	-
Michaelis - Menten Model (MM)	As described and adapted by Lana et al. (2015Lana, R. P., Goes, R. H. T. B., Mancio, A. B., Fonseca, D. M., Moreira, L. M., & Tedeschi, L. O. (2015). Uso do modelo de Lineweaver-Burk de transformação de dados para explicar a resposta animal e vegetal ao nível variável de nutrientes. In R. P. Lana (Org.), Respostas Animais e Plantas aos Nutrientes (p. 27-38). Viçosa, MG: Editora UFV.), in which, data from the literature (Mello et al., 2008Mello, S. Q. S., França, A. F. S., Lanna, A. C., Bergamachine, A. F., Klimann, H. J., Rios, L. C., & Soares, T. V. (2008). Adubação nitrogenada em capim-mombaça: produção, eficiência de conversão e recuperação aparente do nitrogênio. Ciência Animal Brasileira, 9(4), 935-947.) was used to apply to the enzyme kinetic saturation model of Michaelis and Menten (1913), using the linear equation of Lineweaver-Burk (1934), obtaining the kinetic constants Ks (amounts of N and P needed to reach half of the theoretical maximum growth rate, with no application of K₂O due to availability in the soil).	110	10	-