Open-access Forage production and mineral composition of cactus intercropped with legumes and fertilized with different sources of manure

Produção de forragem e composição mineral da palma consorciada com leguminosas e adubada com diferentes fontes de esterco

ABSTRACT:

The objective of this study was to evaluate the productive potential and mineral composition of the forage cactus IPA-Sertânia (Nopalea cochenillifera Salm Dyck). This species was analyzed both in monoculture and intercropped with leucaena [Leucaena leucocephala (Lam.) De Wit.] and gliricidia [Gliricidia sepium (Jacq. Steud.], and was assessed with different sources of manure (cattle, sheep, goat, and broiler litter) serving as fertilizer. The experiment was conducted at the Experimental Station of the Instituto Agronômico de Pernambuco in Caruaru, PE, Brazil. Treatments were allocated in a split-plot arrangement in a randomized complete block design, with four replications. Main plots consisted of cropping systems, while the split-plots were dedicated to manure sources. Cactus harvest was carried out after two years of regrowth. Response variables included both production and nitrogen (N), phosphorus (P), potassium (K), calcium (Ca), and magnesium (Mg) concentrations. No differences were observed for cactus production between the cropping systems, with an average value of 22.1Mg dry matter ha-1 2 years-1. In the intercropped systems, greater proximity to the legumes increased the production of the cactus in the treatments with the cattle and sheep manure, and increased the concentrations of P, K, and Mg, but not of N. The introduction of tree legumes, along with the application of manure, contributes to an increase in production and nutrient concentration of IPA-Sertânia cactus.

Key words: fertilizer; intercropping; minerals; Nopalea; production

RESUMO:

Objetivou-se avaliar o potencial produtivo e a composição mineral da palma forrageira IPA-Sertânia (Nopalea cochenillifera Salm Dyck), em cultivo isolado e consorciada com leucena [Leucaena leucocephala (Lam.) de Wit.] ou gliricídia [Gliricidia sepium (Jacq.) Steud.], e adubada com as fontes de esterco bovino, ovino, caprino e cama de frango. O experimento foi conduzido na Estação Experimental do Instituto Agronômico de Pernambuco - IPA, em Caruaru. O delineamento foi casualizado em blocos, em parcelas subdivididas, com quatro repetições. As parcelas foram representadas pelos sistemas de cultivo e as subparcelas pelas fontes de esterco. A colheita da palma foi realizada aos dois anos de crescimento e analisada quanto à produção e aos teores de nitrogênio (N), fósforo (P), potássio (K), cálcio (Ca) e magnésio (Mg). Não foram observadas diferenças de produção da palma entre os sistemas de cultivo, atingindo valor médio de 22,1t ha-1 2 anos-1 de matéria seca (MS). Nos sistemas consorciados, a maior proximidade com as leguminosas incrementou a produção da palma, nos tratamentos com os estercos bovino e ovino, e elevou os teores de P, K e Mg, mas não os teores de N. A introdução de leguminosas arbóreas, juntamente com a aplicação dos estercos, contribui para elevar a produção e os níveis de nutrientes da palma IPA-Sertânia.

Palavras-chave: adubação; consórcio; minerais; Nopalea; produção

INTRODUCTION:

The spineless cactus IPA Sertânia (Nopalea cochenillifera Salm Dyck) is characterized by its tolerance to arid conditions, high water use efficiency, increased biomass production potential, and resistance to the prickly pear cochineal (LOPES et al., 2010). It is commonly used in the semiarid region of the Northeast Region of Brazil in order to increase forage production and guarantee feed for herds during periods when less is available. Its cladodes are rich in energy, water, minerals, and vitamins; although, it has a low crude protein concentration of 4.8% and a low concentration of fiber (neutral detergent fiber=26.8%; acid detergent fiber=18.8%) (FERREIRA et al., 2012).

Introduction of forage legumes into cactus cultivation can complement animal diets by offering protein and fiber, as well as increasing N availability via biological nitrogen fixation or the decomposition of the corresponding litter, roots, and nodules. Leucaena [Leucaena leucocephala (Lam.) de Wit.] and gliricidia [Gliricidia sepium (Jacq.) Steud.] are tree legumes adapted to the semiarid regions. They present high crude protein (averaging 18 to 30% in their leaves) and biomass production, and can be consumed by ruminants (EDWARDS et al., 2012).

In addition to the intercropping combination, soil fertility management is a main factor in cultivar productivity, particularly in arid and semiarid regions; the corresponding soil generally contains low quantities of organic material. Spineless cacti extract a large quantity of nutrients (DUBEUX JUNIOR et al., 2006) from soil. In addition, their cladodes are taken from the area where they are grown and provided to animals via trough feeding. As such, nutrients are not replaced, which, combined with erosion, tends to diminish productivity after continuous use (RAMOS et al., 2015).

Manure can serve to add organic material to soil, providing plants with nutrients and increasing overall cactus production. Generally speaking, an abundance of organic matter increases the dry matter production of forage cactus. Various studies have assessed manure quantity and source (SANTOS et al., 1996), and have reported linear increases in production up to 80Mg ha-1 of cattle manure applied every two years, with plant density varying from 20,000 to 160,000 plants ha-1 (SILVA et al., 2016). However, manure type has not been studied for cropping systems using tree legumes.

As such, the objective of this research is to evaluate the productive potential and mineral composition of the IPA-Sertânia forage cactus when intercropped with leucaena and gliricidia tree legumes and fertilized with various manure sources.

MATERIALS AND METHODS:

The experiment was performed at the Experimental Station of the Instituto Agronômico de Pernambuco (08º14’18’’S, 35º55’20’’W; altitude of 537m) in Caruaru, PE, Brazil. The local climate is classified as BSh on the Köppen climate classification, specifically as a hot semi-arid climate, with an average annual precipitation of 694mm. The soil in the experimental area is classified as Regolithic Neosoil. A 0-20cm layer of soil was analyzed via the methodology described by EMBRAPA (2011), yielding the following chemical characteristics: pH (H2O)=4.7; Ca2+=1.85cmolc dm-3; Mg2+=0.42cmolc dm-3; K+=0.15cmolc dm-3; Na+=0.07cmolc dm-3; Al3+ =0.27cmolc dm-3; P (Mehlich-1)=19.5mg dm-3; and organic matter=16.5g kg-1.

The experiment was performed using a randomized block design with subdivided plots and four replicates. The primary plot consisted of the following cropping systems: IPA-Sertânia intercropped with leucaena, IPA-Sertânia intercropped with gliricidia, and the cactus in its isolated form. The plots measured 30m×16m. The subplots were divided by fertilizer, with the following manure sources: cattle, sheep, goat, and broiler litter. These covered areas of 30m×4m.

The cactus used in this study was planted in March of 2011, at a spacing of 1m×0.25m, while the legumes were distributed in three double-rows per plot, at a spacing of 9m between each pair, 1m between the rows constituting a pair, and 0.5m between plants in the same row. Fertilization was based on total N concentration, following the recommendation of 200kg ha-1 of N and correcting the dry matter concentration of the manure. Manure was applied in 2012 and 2013, while the cactus was harvested at the end of each year, and in 2015. Manures were distributed between the cactus lines, excluding the double-rows of legumes.

The cacti were collected in April 2016, with the original portions preserved after each cut. In the intercropped cultivation group, plants were harvested at a distance of 1, 2, 3, and 4m from the legumes, with 2 plants/distances/subplots being sampled. For the isolated cultivation group, this corresponded to 4 plants/subplots. The plants were weighed in the field. One composite sample was made and pre-dried in a forced air circulation oven at 55ºC until reaching a constant weight (SILVA & QUEIROZ, 2009). Dry matter production (DMP) was calculated based on the plant density per subplot.

N concentration was obtained via dry combustion, using the Dumas method (Vario Micro Cube, Elementar, Hanau, Germany). To determine P, K, Ca, and Mg concentration, the samples were digested in a mixture of nitric acid and perchloric acid (5:1mL) and analyzed according to the methodology described by BEZERRA NETO & BARRETO (2004).

Analysis of variance was carried out using PROC MIXED by SAS (SAS, 1999). The fixed effects were the cropping system, manure sources, and distances of the legume double-rows. The block was analyzed as a random effect. When the F-test was significant, the treatment means were compared using Tukey’s test at 5% probability. Collection distances were submitted to regression analysis.

RESULTS AND DISCUSSION:

No differences were observed in the production of cactus dry matter between the studied cropping systems (Table 1). This is likely the case due to the residual effect of fertilizing in 2012, 2013, and 2015 with the same manure sources. Given the passage of five years after establishing the intercropping, these results demonstrated that both the sources and the quantity of utilized manure were adequate, to the effect that the residual influence of the manure reduced the competitive effect of the legumes on the cactus.

Table 1
Dry matter production (DMP) and phosphorus (P) and potassium (K) concentration in IPA-Sertânia cactus cultivated in different cropping systems in Caruaru, PE.

P and K concentrations differed (P<0.05) between the cropping systems (Table 1). Cactus P concentration in the gliricidia samples was greater than in the leucaena samples but did not differ from the isolated samples. This could be the result of lower deposition and contribution of this nutrient from the leadtree litter, as observed by BERTALOT et al. (2004). The greatest concentration of K was obtained with the isolated samples, which could be the result of the absence of competition and the high demand for this nutrient by the cactus (DUBEUX JÚNIOR et al., 2006). However, this value did not differ (P<0.05) from that of the gliricidia sample, likely due to the higher concentrations of this nutrient in the upper part of the gliricidia (BARRETO & FERNANDES, 2001). These results indicated that gliricidia contributes to P and K concentrations in intercropping with the cactus.

A correlation was observed (P<0.05) between distances between the legume and manure lines and production of cactus dry matter and N concentration (Table 2). The greatest cactus production was obtained at 1 m using cattle and sheep manure. A regression analysis of these samples showed a quadratic effect (P<0.05), indicating a decrease in production at 2 m, with an increase after 3 and 4 m. The greatest production being at the lowest distance might be the result of greater legume litter deposits (SILVA et al., 2013) and the greater application of manure and; consequently, macronutrients. Conversely, this greater quantity could have yielded improvements in the soil properties, such as greater retention of humidity and water availability (SILVA et al., 2004), which would in turn favor nutrient absorption and, consequently, greater production.

Table 2
Dry matter production (DMP) and nitrogen (N) concentration in IPA-Sertânia cactus at different distances between double-rows of legumes and manure sources in Caruaru, PE.

Regression analysis of the broiler litter fertilizer showed a linear effect (P<0.05), indicating a reduction in the production of dry matter as legume distance increased. This is likely due to a decrease in overall manure and litter deposition at increased distances.

Meanwhile, regression analysis of cactus N concentration (Table 2) was not significant for either a linear or quadratic effect with respect to distance for any manure. N concentration differed with distance for goat manure and broiler litter, with the lowest values observed for a legume distance of 2m. However, for cattle and sheep manure, no differences were observed with respect to distance. These observations may result from a low or nonexistent contribution made by legumes to biological N fixation, which could have resulted from the fact that rainfall in the years preceding cactus harvesting was lighter than normal for the area. Moreover, the supply of organic N in the soil solution from fertilizing with manure could have inhibited symbiosis between plant roots and N fixing bacteria.

Generally, the greatest N concentrations were obtained with broiler litter, likely due to the more rapid decomposition and accompanying release of N inherent to this material. SILVA et al. (2014), when evaluating cattle manure and broiler litter in Red-Yellow Acrisol, reported a more rapid decomposition in the first 30 days for the broiler litter. This was accompanied by a faster initial release of N, which slowed down in the subsequent periods.

Legume distance affected (P<0.05) K and Mg concentrations in the cactus (Table 3). K concentration varied linearly. Regression analysis indicated a decrease in concentration as distance increased, seeing how the greatest deposition of litter and nutrients occurs in the bands closest to the trees. Conversely, Mg concentration showed a quadratic effect, with a decrease at 2m; this may be because, at this distance, there is greater competition with the legumes for this nutrient.

Table 3
Potassium (K) and magnesium (Mg) concentration in IPA-Sertânia cactus at different distances between double-rows of legumes in Caruaru, PE.

Manure source had an effect (P<0.05) on N, K, Ca, and Mg cactus concentrations (Table 4). Although, fertilizing was performed based on N concentration, following the recommendation of 200kg ha-1, the greatest quantities of this nutrient were obtained using broiler litter, likely as a function of the more rapid decomposition. According to MINSON (1990), for normal rumen function, the crude protein concentration of forage should be, at least, 70g kg-1, or 11.2g kg-1 of N in dry matter. However, the average N values reported in this study were lower than those indicated. As such, it will be necessary to include dietary supplements with protein sources, such as legumes, not only in order to increase dry matter and protein intake, but also to correct for the diarrhea that would result when this food source is supplied alone or consumed freely (GALVÃO JÚNIOR et al., 2014).

Table 4
Nitrogen (N), potassium (K), calcium (Ca), and magnesium (Mg) concentration in IPA-Sertânia cactus fertilized with different manure sources in Caruaru, PE.

Generally, cactus K, Ca, and Mg concentration were lower when using broiler litter as a fertilizer given the lower applied quantity of this manure and; consequently, the lower amount of other macronutrients.

CONCLUSION:

Intercropping IPA-Sertânia cactus with leucaena or gliricidia, or cultivating it alone, does not influence DMP, but influences the composition of macronutrients in the cactus, with the best results obtained for cactus cultivated alone and with gliricidia.

The distance between the legume rows and the manure sources utilized for fertilizing influences production and N concentration in cactus that is intercropped with leucaena and gliricidia.

ACKNOWLEDGEMENTS

The authors appreciated the CNPq fellowship provided to Dr. Mercia Santos and Dr. Alexandre Mello and the Graduate Assistantship funded by FACEPE to fund the PhD of Dr. Karina Miranda.

REFERENCES:

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    CR-2018-0324.R2

Publication Dates

  • Publication in this collection
    2019

History

  • Received
    17 Apr 2018
  • Accepted
    19 Nov 2018
  • Reviewed
    19 Dec 2018
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