American Journal of Plant Sciences
Vol.5 No.7(2014), Article ID:44157,9 pages DOI:10.4236/ajps.2014.57106

Yield and Chemical Composition of Brachiaria Forage Grasses in the Offseason after Corn Harvest

Gean Alves Maia1, Kátia Aparecida de Pinho Costa2, Eduardo da Costa Severiano1, Patrícia Soares Epifanio2, José Flávio Neto1, Matheus Gonçalves Ribeiro2, Patrick Bezerra Fernandes2, José Fausto Guimarães Silva1, Wainer Gomes Gonçalves1

1Laboratory of Soil Physics, Federal Institute Goiano, Rio Verde, Brazil

2Laboratory of Forage and Grassland, Federal Institute Goiano, Rio Verde, Brazil

Email: eduardo.severiano@ifgoiano.edu.br

Copyright © 2014 by authors and Scientific Research Publishing Inc.

This work is licensed under the Creative Commons Attribution International License (CC BY).

http://creativecommons.org/licenses/by/4.0/

Received 15 January 2014; revised 16 February 2014; accepted 1 March 2014

ABSTRACT

This study evaluated the dry matter production and chemical composition of Brachiaria forage grasses in the offseason after corn harvest in integrated crop-livestock system. The experiment was conducted at the Federal Institute of Goiás, Rio Verde Campus, using a randomized complete block experimental design, with four replications. The treatments consisted of the forages: Brachiaria brizantha cv. Marandu; Brachiaria brizantha cv. Xaraes; Brachiaria brizantha cv. Piata; Brachiaria brizantha cv. MG-4; Brachiaria decumbens and Brachiaria ruziziensis, intercropped in oversown corn for implantation of integrated crop-livestock system. The results showed that intercropping corn with Brachiaria grasses favors the production of high-quality forage in the offseason, and the cultivars of Brachiaria brizantha and Brachiaria decumbens showed higher dry matter production. And cultivars of Brachiaria brizantha (Marandu palisadegrass, Xaraes palisadegrass and Piata palisadegrass) are the most suitable for presenting food of better quality, compared with Brachiaria brizantha cv. MG-4, Brachiaria decumbens and Brachiaria ruziziensis.

Keywords:Brachiaria brizantha; Brachiaria decumbens; Brachiaria ruziziensis; Crop-Livestock Integration

1. Introduction

In recent years, intercropping between annual crops and tropical forages, known as integrated crop-livestock system, has been increasingly adopted by farmers in the Cerrado [1] , especially because studies demonstrated the feasibility of the intercrop between the annual culture and the various forage species simultaneously planted [2] . This system consists of the exploitation of the same area with the purpose of producing grains and livestock farming (production of meat, milk, etc.) [3] , with the potential to increase yield and reduce the risk of degradation of pastures, thus improving the chemical, physical and biological soil properties, and yield potential of grain, forage and silage [4] . Moreover, [5] it is reported that this technique stands out as being part of sustainable and competitive technologies to boost the Brazilian agribusiness. Among the forages for crop rotation, succession or intercropping in the Cerrado region [6] stands out the Brachiaria grasses. The advantages of using this genus in integrated system are because these species have abundant roots which contribute to the collection of water, soil aggregation and aeration [7] . Furthermore, these forages have good adaptability, tolerance, and resistance to biotic factors and show high dry matter production with good nutritional value, capable of meeting the requirements of animals, especially in the dry season [8] .

Identifying the best association between annual crops and different species of Brachiaria allows the exploitation of grain and biomass. After harvesting the grain, the area will be used as a standard pasture. The use of more productive forages during the dry season is important because they minimize the effect of the seasonality of production. In this way, the forage is suitable for intercropping in addition to promoting grain production of annual crops, and it must have good establishment and growth when intercropped, as well as major forage production [9] .

However, most studies on crop-livestock integration evaluate the use of Brachiaria brizantha cv. Marandu, Brachiaria decumbens and Brachiaria ruziziensis [10] , and the release of new cultivars of Brachiaria brizantha is lacking in information about the cultivars xaraés and piatã, especially regarding the yield and quality of these forages when subjected to intercropping in the offseason. Therefore, the identification of the best association between annual crops of different Brachiaria species allows the exploitation of grain production [11] and forage production in the winter, which shows low forage production. Once restored, the pastures have better nutritional value in autumn-winter, alleviating the pronounced effect of seasonality. In view of this, considering the importance of supplying better quality food, the present study aimed to evaluate the dry matter production and chemical composition of Brachiaria forage grasses in the offseason after corn harvest in integrated crop-livestock system.

2. Material and Methods

The study was conducted in an experimental area of 2016 m2 at the Federal Institute of Education, Science and Technology Goiano—Rio Verde Campus, Rio Verde, Goiás State, 17˚48’34.25"S and 50˚54’05, 36"O, at 731 meters above sea level. The climate was classified according to Köppen, as megathermal or Humid Tropical (Aw), subtype Tropical Savanna, with dry winter and rainy summer. The average annual temperature is 25˚C and the average annual rainfall is about 1600 mm, with maximum rainfall in January and lowest in June, July and August (<50 mm∙month−1). The soil was classified as Dystroferric Red Latosol [12] , with 530 g∙kg−1 clay, 250 g∙kg−1 silt and 220 g∙kg−1 sand. The chemical characteristics of the soil at 0-20 cm before planting are presented in Table 1.

Corn (Zea mays) was sown in the first crop, on November 19th, 2010, with the aim of producing forage for silage. We used a row spacing of 0.8 m, with a population of 55,000 plants∙ha−1. For planting it was applied 200 kg∙ha−1 P2O5, 30 kg∙ha−1 nitrogen, 60 kg∙ha−1 K2O, 2 kg∙ha−1 boron, 0.4 kg∙ha−1 molybdenum, using as sources: simple superphosphate, potassium chloride, boric acid and sodium molybdate. After crop emergence, plant thinning was carried out in carriers and plots were delimited with dimensions of 5.4 × 6 m (32.4 m2), randomly arranged into four blocks. Twenty-five days after corn sowing, Brachiaria forage grasses were planted in over-sowing corn for implantation of integrated crop-livestock system. Topdressing fertilization of corn was

Table 1. Chemical characteristics of the Dystroferric Red Latosol under integrated crop-livestock systems during sowing of Brachiaria species intercropped with corn (crop 2010/2011).

(1)20 cm depth; (2)V: base saturation; (3)m: aluminum saturation; (4)OM: Organic Matter. P: Determined by Mehlich extractor.

performed thirty days after emergence with 30 kg∙ha−1 nitrogen and 90 kg∙ha−1 K2O, using ammonium sulphate and potassium chloride. The experiment consisted of a randomized complete block experimental design, with four replications. Treatments were comprised of the forages: Brachiaria brizantha cv. Marandu; Brachiaria brizantha cv. Xaraes; Brachiaria brizantha cv. Piata; Brachiaria brizantha cv. MG-4; Brachiaria decumbens and Brachiaria ruziziensis, intercropped in over-sowing corn for implantation of integrated crop-livestock system. Corn for silage was harvested mechanically at 90 days after sowing, on February 17th, 2011, with dry matter content ranging from 30% to 35%. To evaluate the development of Brachiaria, depending on climatic seasonality, after corn harvest, were conducted topdressing of 50 kg∙ha−1 nitrogen and 25 kg∙ha−1 K2O, using urea and potassium chloride, respectively. In October of the same year (beginning of the rainy season) was applied the same amount of nitrogen and potassium. The evaluation periods of dry matter production and nutritive value of forages were conducted during the dry season and at the beginning of the rainy season. In this period were monitored daily rainfall data and monthly mean temperature (Figure 1).

Forages were evaluated under successive cuts, being collected samples of 1 m2, by randomly directing the square within each plot and cutting at 20 cm height for cultivars of Brachiaria brizantha and at 15 cm for Brachiaria decumbens and Brachiaria ruziziensis. Cuts were held on 21/03/2011 (1st cut), 11/05/2011 (2nd cut), 04/07/2011 (3rd cut), 12/09/2011 (4th cut), 24/10/2011 (5th cut) and 25/11/2011 (6th cut). After assessment, the cut was made to standardize the experimental area, at the same height of the plants evaluated, being removed the residue from the area. The material collected in the field was packed in plastic bags and sent to the laboratory where a representative sample (500 g) of each plot was pre-dried in a forced air oven at 55˚C. Subsequently, samples were ground in a Willey mill, with 1 mm sieve and stored in plastic bags for analysis. Chemical analyses were performed to determine the dry matter (DM), crude protein (CP), neutral detergent fiber (NDF) and acid detergent fiber (ADF) using the method described by [13] . For determining in vitro dry matter digestibility (IVDMD), we adopted the technique described by [14] , adapted to the artificial rumen, developed by ANKON®, using the instrument “Daisy incubator” of Ankom Technology (in vitro true digestibilityIVDMD). The ruminal fluid collection was performed by two cannulated steers with an average weight of 550 kg; animals were kept on pasture of Brachiaria brizantha cv. Marandu. Data were subjected to analysis of variance and means were compared by Tukey’s test, with significance level of 5% probability. Analyses were performed by the split plot model over time, according to linear Gauss Markov models using the software SISVAR [15] .

3. Results and Discussion

Significant effects (P < 0.05) were detected for the production of dry matter, crude protein (CP), neutral detergent fiber (NDF), acid detergent fiber (ADF), hemicellulose and in vitro dry matter digestibility (IVDMD) for forages of Brachiaria species, cuts, as well as the interaction of these factors. Assessing the dry matter production of cuts between Brachiaria species (Table 2), it is observed that in the first and sixth cut, higher yield was achieved in Brachiaria brizantha cv. Piatã. Although mid-sized and with a height between 0.85 m and 1.10 m, the Piata palisadegrass has good forage yield, high percentage of leaves and thin stems, which results in higher leaf: stem ratio, and better utilization by the [16] . Researches have shown that in plots under cutting the Piata

Figure 1. Rainfall (mm) and monthly temperature (˚C) during cultivation of Brachiaria forage grasses, Rio Verde, Goiás State.                              

Table 2. Dry matter production (kg∙ha−1) of Brachiaria species in different cuts after corn harvest in the offseason.

Means followed by different upper cases in the column (cultivars) and lower cases in the row (cuts) are significantly different by Tukey’s test (P < 0.05). (1)Sum of production of the six evaluation cuts.

palisadegrass produced an average of 9.5 tons per hectare of dry weight, with 57% leaves, 30% yield obtained in the dry season [17] . In addition to the production and nutritional qualities, [18] reported that Piatã grass is indicated for use in crop-livestock integration system, due to the slower initial growth, compared with Marandu palisadegrass and Xaraes palisadegrass and high growth after harvest of annual crops. These characteristics make the cultivar BRS Piata palisadegrass an excellent alternative for reducing large areas characterized by monocultures of Marandu palisadegrass, currently existing in all states of the Midwest and Southeast regions [19] . In the second cut, when begins the dry period, the highest yield was of Brachiaria brizantha cv. MG-4. Similar results were found by [9] , which evaluated the agronomic performance of genotypes of signal grass succeeding soybeans, and verified that in 2007, the cultivar MG-4 produced 4984 kg∙ha1 dry matter of forage, and was superior to Piata palisadegrass and Arapoty grasses, but was not different from palisade, Xaraes palisadegrass and B6 lineage (Paiaguas palisadegrass). Cultivars of Brachiaria brizantha and Brachiaria decumbens in the third, fourth and fifth cuts presented similar yields, differing only from Brachiaria ruziziensis that showed the lowest yield.

It is worth mentioning that even with a drastic reduction of forage production in the dry season (third, fourth and fifth cuts) in relation to the cuts in the rainy season (first, second and sixth cuts), the highest average yields were obtained by cultivars Brachiaria brizantha and Brachiaria decumbens (Table 2). These results demonstrate that these forages are more suitable for the supply of food in the offseason, after harvest of annual crops, in order to minimize the seasonality of forage production.

Evaluating the content of CP of the cuts between Brachiaria species (Table 3), it in the first cut (March) and Xaraes palisadegrass and Piata palisadegrass showed the highest values, differing from the other species with similar contents. In the second cut, the Piata palisadegrass also had the highest CP content. However, in the third cut, in July, the content of CP was similar between all cultivars of Brachiaria brizantha, only differing from Brachiaria decumbens and ruziziensis. In the fourth cut, Xaraes palisadegrass, MG-4 palisadegrass and ruziziensis exhibited the lowest contents of CP, and in the fifth and sixth, the highest contents were registered in marandu, xaraés and piatã grasses. Importantly, for all cuts in different seasons, the Piata palisadegrass reached the highest content of crude protein. This result is due to the higher leaf:stem ratio present in this grass [17] , and also to the highest yields of dry matter (Table 2), indicating that it is an excellent forage for use in the offseason.

Comparing the Brachiaria species within each cut (Table 3), it is observed that for Marandu palisadegrass, MG-4 palisadegrass, Piata palisadegrass and Brachiaria ruziziensis, lower values of CP were obtained in the fourth cut. This result is due to unfavorable weather conditions during this period, with low rainfall, which was the limiting factor for the development of forages, impairing the growth and formation of new tillers. Moreover, due to lack of rainfall, forages were cut in the growth cycle of 70 days (4th cut) and not in the shorter cycle as in the other cuts (1st cut: 33 days; 2nd cut: 50 days; 3rd cut: 44 days, 5th cut: 42 days and 6th cut: 32 days) certainly leading pasture to maturity due to the seasonality of forage production. A similar result was obtained by [20] that evaluated the effect of season on the nutritional values of Marandu palisadegrass, and reported higher values of CP during the rainy season (9.7%) when compared to dry season (8.9%). It is interesting the high crude protein obtained in the third cut (July). During winter CP usually decreases, given the low temperatures and lack of rainfall, damaging the development of forage. These results indicate the importance of crop-livestock integration, to provide quality food in the winter. From the fifth cut, there was an increase in CP, owing to the beginning of the rainy season and the topdressing fertilization (nitrogen and potassium). Importantly, in periods of low rainfall

Table 3. Content of CP (%) of Brachiaria species in different cuts after corn harvest in the offseason.

Means followed by different upper cases in the column (cultivars) and lower cases in the row (cuts) are significantly different by Tukey’s test (P < 0.05).

(winter), when the forage growth is impaired, it is required a management strategy that result in higher percentages of green leaves in the pasture, to contribute and improve the nutritional value of forage during this period. [21] verified that a reduction in the period when the pasture remains deferred and accomplishment of fertilization with nitrogen can contribute to the occurrence of larger mass of green foliage and lower masses of stem and dead material in the forage, being therefore actions recommended for, among other things, improving the nutritional value of deferred forage in some regions. Comparative studies were developed by [22] who evaluated the nutritional values of Marandu palisadegrass, Xaraes palisadegrass and Piata palisadegrass and showed that regardless of the experimental year, the CP were higher during the rainy season. Even presenting a decline in the CP content in the dry season, levels remained above the critical level quoted by [23] for the satisfactory development of ruminal cellulolytic bacteria, that is, the CP content must be equal to or higher than 7.0%. Similar contents were also obtained by [24] , who found that the Brachiaria decumbens had CP content of 11.69%, 11.08%, 9.43% and 8.93% in spring, summer, autumn and winter, respectively, showing the reduction of CP content during the winter period due to the maturity of the plant. Evaluating fiber fractions of the cuts between Brachiaria species (Table 4), in the first cut only Brachiaria ruziziensis differed from the Piata palisadegrass with higher NDF (70.08%). In the second cut, Xaraes palisadegrass had the lowest NDF. In the third cut NDF were similar between Brachiaria species. In the fourth cut, MG4 palisadegrass and Brachiaria decumbens grasses showed the highest NDF. However, for all forages in the fourth cut, the values were high and varied from 71.43% to 75.07%, given the low amount of leaves and high of stem owing to the low development of forages in the dry period, due to unfavorable weather conditions for forage development and to forage maturation [25] . From the beginning of the rainy season (fifth and sixth cuts), there was a reduction in NDF (Table 4), Piata palisadegrass had the lowest concentrations due to its high percentage of leaves and thin stems, resulting in better quality forage [16] .

Comparing the contents of NDF between Brachiaria species in different cuts (Table 4), we observed higher NDF contents of Brachiaria brizantha cv. Marandu and Brachiaria decumbens in fourth and fifth cuts. For Brachiaria brizantha cvs. MG-4, Xaraés and Piatã grasses, the highest contents were recorded in the fourth cut. And for Brachiaria ruziziensis the content of NDF was similar between the first, second, fourth and fifth cuts, only the third and sixth cuts had reduced contents of NDF. For all forages, NDF contents in the fourth cut were above 72%, which can cause low intake. [26] reported that NDF is relevant to the improvement of the forage nutritional value and can be an important parameter to define the forage quality, because the more fibrous pasture occupies more space for longer and limits the intake rate. Similarly, [27] evaluated the Marandu palisadegrass intercropped with corn and obtained 72% NDF. [28] studied the chemical composition of Braquiarias after intercropping with corn and achieved NDF content above 60% for Marandu palisadegrass and ruziziensis grasses. Furthermore, [10] examined four cultivars of Brachiaria intercropped with corn and reported NDF content of 66.4% - 74.3% and 70.3% - 78.1% for mulato grass and Marandu palisadegrass, respectively. It is important to stress that along all cuts, Piata palisadegrass and Xaraes palisadegrass showed less variation in NDF, where weather conditions were influenced, showing greater flexibility when subjected to water deficit, as they presented high regrowth rate [16] . These features make these cultivars excellent alternative for use in the integrated crop-livestock systems, with the purpose of providing quality food in the dry season. By examining the contents of ADF of cuts between Brachiaria species (Table 5), in the first cut Brachiaria brizantha cv. Marandu and Brachiaria ruziziensis showed the highest content of ADF, differing from other species. In the second cut,

Table 4. Content of NDF (%) of Brachiaria species in different cuts after corn harvest in the offseason.

Means followed by different upper cases in the column (cultivars) and lower cases in the row (cuts) are significantly different by Tukey’s test (P < 0.05).

Table 5. Content of ADF (%) of Brachiaria species in different cuts after corn harvest in the offseason.

Means followed by different upper cases in the column (cultivars) and lower cases in the row (cuts) are significantly different by Tukey’s test (P < 0.05).

only Brachiaria ruziziensis was different from palisadegrass Xaraés and palisadegrass Piatã, with high ADF content (41.53%). Nevertheless, from the third to the sixth cut the cultivars xaraés and piatã presented lower content of ADF, differing from brizantha (Marandu palisadegrass and MG-4 palisadegrass) and Brachiaria decumbens and ruziziensis. This may be correlated with the better regrowth of these grasses in the dry period.

When compared the ADF content of Brachiaria species in the different cuts (Table 5), for all species the highest levels were achieved in the fourth cut, because it was held in the growth cycle of 70 days, causing the maturation of the pasture, due to the seasonality of forage production. In this context, the digestibility of foods is related to the fiber because the indigestible portion has a proportion of ADF, and the higher the value of ADF the lower the food digestibility [29] . [30] reported that forage with ADF content around 40%, or more, shows low intake and digestibility. In the present study only in the fourth cut the ADF content remained above 40%. For the other cuts, forages exhibited content below 40%, indicating that intercropping annual crops with forages is a good option for providing quality food at critical periods of drought, as from the corn harvest; there is recovery of emergence of new tillers, providing yield and forage with good digestibility. Evaluating the IVDMD of cuts between Brachiaria species (Table 6), in all cuts higher IVDMD values were obtained in Brachiaria brizantha cvs. Xaraes and Piata, being different from other grasses, which showed similar IVDMD. These results can be related to higher content of CP and lower fiber fractions obtained for these grasses (Tables 3-5). [31] argued that increased digestibility is probably associated with shifts in the chemical composition with decreased content of NDF, ADF and hemicellulose, which certainly make available readily digestible carbohydrates for rumen microorganisms. Nevertheless, when comparing the IVDMD of Brachiaria species in different cuts (Table 6), for all cultivars of Brachiaria brizantha, the highest values were detected in the first, second, fifth and sixth cuts. These results are probably due to the better development of these forages, because in these periods, climatic conditions such as temperature and rainfall were favorable for the production of new tillers. However, for Brachiaria decumbens and ruziziensis, only the IVDMD of the fourth cut was different from the other cuts. For all forages, lowest IVDMD were obtained in the fourth cut. These results may possibly be explained by the most advanced physiological maturity, due to the seasonality of forage production, undermining the development of forages, once they were cut in the longer growth cycle (70 days), compared to other cuts which were performed in shorter cycles, and with this increases the cell wall components and reduces digestibility.

Table 6. Content of in vitro dry matter digestibility (%) of Brachiaria species in different cuts after corn harvest in the offseason.

Means followed by different upper cases in the column (cultivars) and lower cases in the row (cuts) are significantly different by Tukey’s test (P < 0.05).

Nevertheless, when comparing the IVDMD of Brachiaria species in different cuts (Table 6), for all cultivars of Brachiaria brizantha, the highest values were detected in the first, second, fifth and sixth cuts. These results are probably due to the better development of these forages, because in these periods, climatic conditions such as temperature and rainfall were favorable for the production of new tillers. However, for Brachiaria decumbens and ruziziensis, only the IVDMD of the fourth cut was different from the other cuts. For all forages, lowest IVDMD were obtained in the fourth cut. These results may possibly be explained by the most advanced physiological maturity, due to the seasonality of forage production, undermining the development of forages, once they were cut in the longer growth cycle (70 days), compared to other cuts which were performed in shorter cycles, and with this increases the cell wall components and reduces digestibility. Note that with the exception of the fourth cut, the digestibility is considered high for the offseason; it shows once again the importance of crop-livestock integration, for supplying high quality food in the dry season, when low production and forage quality are obtained under normal conditions. [9] investigated genotypes of Brachiaria brizantha succeeding soybeans in integrated crop-livestock systems, and found a digestibility similar to that of the present study in the offseason with values in 2009 at 74.9%, 74.0%, 67.8%, 71.6%, 83.7% and 77.3% for Marandu palisadegrass, MG-4 palisadegrass, Xaraes palisadegrass, Piata palisadegrass, arapoty and B6 (Paiaguas palisadegrass), respectively.

4. Conclusion

Intercropping corn with Brachiaria species favors the production of high quality forage in the offseason, and the cultivars of Brachiaria brizantha and Brachiaria decumbens show higher production of dry matter. And cultivars of Brachiaria brizantha (Marandu palisadegrass, Xaraes palisadegrass and Piata palisadegrass) are the most suitable for presenting food of better quality, compared with Brachiaria brizantha cv. MG-4, Brachiaria decumbens and Brachiaria ruziziensis.

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