Food quantity and quality of cassava affected by leguminous residues and inorganic nitrogen application in a soil of low natural fertility of the humid tropics

Moura-Silva, Aline Gomes; Aguiar, Alana das Chagas Ferreira; Jorge, Neuza; Agostini-Costa, Tânia da Silveira; Moura, Emanoel Gomes

doi:10.1590/1678-4499.007

ABSTRACT

The aim of this study was to test the hypothesis that the quality and quantity of biofortified cassava root in a humid tropical environment can be modified with the application of a combination of low- and high-quality residues of leguminous tree species. The experiment was designed as a 6 × 2 factorial (a combination of 4 legume species versus 2 levels of nitrogen) with 4 replications in a randomized block design and the following treatments: Gliricidia + Acacia, Gliricidia + Leucaena, Gliricidia + Clitoria, Leucaena + Acacia, Leucaena + Clitoria, and a control without legumes. We analyzed the shoot weight, number of roots/plant, root weight, root production, proximate composition, as well as the mineral, carotenoid, and pro-vitamin A contents. Root production increased with the application of high-quality residues. The protein level influenced the carotenoid content. The allelopathic effect of exotic genera — Leucaena and Acacia —, especially when combined, can decrease the mineral content such as potassium and, therefore, reduce the accumulation of starch.

Key words
biofortification; food security; green manure; nutrients

INTRODUCTION

Cassava is one of the first crops that were domesticated and has been used for centuries as a food source by many cultures. This crop is consumed by millions of people in tropical and subtropical regions, being a main food staple in large regions of Africa and Latin America. Cassava is vital for both food security and income generation for these people and their families (Kaweewong et al. 2013Kaweewong, J., Kongkeaw, T., Tawornprek, S., Yampracha, S. and Yost, R. (2013). Nitrogen requirements of cassava in selected soils of Thailand. Journal of Agriculture and Rural Development in the Tropics and Subtropics, 114, 13-19.). The important role cassava plays in maintaining food security can be attributed to its ease of cultivation and tolerance of poor soils, low rainfall, and high temperatures. In addition, cassava does not require management as intensive as that required by other crops, such as maize, wheat, and rice; besides, it can withstand drought and be stored in fields for long periods of time (Burns et al. 2012Burns, A. E., Gleadow, R. M., Zacarias, A. M., Cuambe, C. E., Miller, R. E. and Cavagnaro, T. R. (2012). Variations in the chemical composition of cassava (Manihot esculenta Crantz) leaves and roots as affected by genotypic and environmental variation. Journal of Agricultural and Food Chemistry, 60, 4946-4956. http://dx.doi.org/10.1021/jf2047288.
http://dx.doi.org/10.1021/jf2047288... ).

A meal comprising 500 g of cassava products provides almost the entire minimum daily requirement for energy needs, but only a small part of the minimum daily requirement of vitamin A, protein, iron, and zinc. This is especially critical for poor families for whom cassava constitutes almost the entire daily primary meal and who cannot afford the expensive alternative sources of these nutrients (Montagnac et al. 2009Montagnac, J. A., Davis, C. R. and Tanumihardjo, S. A. (2009). Nutritional value of cassava for use as a staple food and recent advances for improvement. Comprehensive Reviews in Food Science and Food Safety, 8, 181-194. http:/dx.doi.org/10.1111/j.1541-4337.2009.00077.x.
http:/dx.doi.org/10.1111/j.1541-4337.200... ). This has resulted in the need to develop an alternative that provides these essential nutrients as well as the energy requirements of the body.

Therefore, while product quantity is the principal function that drives producer revenue stream, product quality is also important for driving economic and social return. Biofortification is the process by which the nutritional quality of food crops is improved through agronomic practices, conventional plant breeding, or modern biotechnology. The biofortification process for improving the food quality of cassava has been very successful, particularly in ß-carotene content. However, adverse environmental effects such as low nitrogen (N) availability may impose severe constraints on the exploitation of this important alternative crop for family farms (Ngaboyisonga et al. 2012Ngaboyisonga, C., Njoroge, K., Kirubi, D. and Githiri, S. M. (2012). Quality protein maize under low N and drought environments: endosperm modification, protein and tryptophan concentrations in grains. Agricultural Journal, 7, 327-338. http://dx.doi.org/10.3923/aj.2012.327.338.
http://dx.doi.org/10.3923/aj.2012.327.33... ).

Unfortunately, in the humid tropics, high temperatures and rainfall combined with soils derived from clastic sedimentary rocks result in unfavorable conditions for organic matter accumulation and thus N availability. In particular, a continuous crop of cassava in the same area reduces nutrient availability and results in the depletion of soil fertility. These factors are now increasingly recognized as the fundamental causes of deforestation and decline food security in small landholder farms in the Amazon region and its surroundings (Aguiar et al. 2011Aguiar, A. C. F., Freitas, I. C., Carvalho, C. S., Monroe, P. H. M. and Moura, E. G. (2011). Efficiency of an agrosystem designed for family farming in the pre-Amazon region. Renewable Agriculture and Food Systems, 26, 24-30. http://dx.doi.org/10.1017/S1742170510000396.
http://dx.doi.org/10.1017/S1742170510000... ). To circumvent these obstacles, farmers in the pre-Amazon region practice itinerant agriculture that is associated with the slashing and burning of natural vegetation where cassava plays an important role due to its tolerance for low-input systems. Unfortunately, this system has negative effects on the local and global environment and no longer provides social benefits to rural communities (Moura et al. 2014Moura, E. G., Marques, E. S., Silva, T. M. B., Piedade, A. and Aguiar, A. C. F. (2014). Interactions among leguminous trees, crops and weeds in a no-till alley cropping system. International Journal of Plant Production, 8, 441-456.).

No-tillage alley cropping can be an efficient strategy for maintaining productivity in the low-fertility soils of humid tropical regions because this practice increases the availability and efficient use of nutrients. This system can be described as the planting of trees or shrubs in 2 or more sets of single or multiple rows. Before and during the cropping period, the leguminous branches are periodically pruned and laid down on the soil surface between the leguminous tree sets (Aguiar et al. 2010Aguiar, A. C. F., Bicudo, S. J., Costa Sobrinho, J. R. S., Martins, A. L. S., Coelho, K. P. and Moura, E. G. (2010). Nutrient recycling and physical indicators of an alley cropping system in a sandy loam soil in the pre-Amazon region of Brazil. Nutrient Cycling in Agroecosystems, 86, 189-198. http://dx.doi.org/10.1007/s10705-009-9283-6
http://dx.doi.org/10.1007/s10705-009-928... ).

The efficiency of this system can be increased with the combined use of low- and high-quality residues of different leguminous tree species. First, soil rootability is enhanced by low-quality durable residues that increase nutrient uptake and nutrient use efficiency; second, the application of high-quality residues increases nutrient recycling, which enhances nutrient availability. However, trees also modify the biophysical environment in favor of their own growth preferences. Therefore, various negative or antagonistic interactions, both competitive and allelopathic, may influence the crop components of agroforestry systems (Moura et al. 2013Moura, E. G., Monroe, P. H. M., Coelho, M.J.A., Costa Sobrinho, J.R.S. and Aguiar, A.C.F. (2013). Effectiveness of calcined rock phosphate and leucaena prunings as a source of nutrients for maize in a tropical soil. Biological Agriculture & Horticulture, 29, 132-144. http://dx.doi.org/10.1080/01448765.2013.781486.
http://dx.doi.org/10.1080/01448765.2013.... ).

Therefore, we hypothesized that the quality and quantity of cassava roots can be modified by green manure with the combined use of low- and high-quality leguminous residues in a humid tropic environment. Thus, the overall aim of this study was to test this hypothesis and identify a combination of leguminous residues of low/high quality that increase yield and the contents of essential human nutrients in cassava roots.

MATERIAL AND METHODS

Experimental site and trial establishment

The study area is located in the municipality of São Luís, in the northeast of the Maranhão State, at the following geographic coordinates: lat 2°30′S and long 44°18′W. The region has a hot, semi-humid, equatorial climate with a mean precipitation of 2,100 mm∙year^–1 and 2 well-defined seasons: a rainy one that extends from January to June and a dry season with a pronounced water deficit from July to December. The average temperature is approximately 27 °C, the maximum one is 37 °C, and the minimum temperature is 23 °C. The local soil is classified as an Arenic Hapludult and consists of 260 g∙kg^–1 of coarse sand, 560 g∙kg^–1 of fine sand, 80 g∙kg^–1 of silt, and 100 g∙kg^–1 of clay. The soil is derived from sedimentary clastic rock with a low carbon content and a high fine sand content; therefore, it has hardsetting characteristics (Moura et al. 2009Moura, E. G., Moura, N. G., Marques, E. S., Pinheiro, K. M., Costa Sobrinho, J. R. S. and Aguiar, A. C. F. (2009). Evaluating chemical and physical quality indicators for a structurally fragile tropical soil. Soil Use and Management, 25, 368-375. http://dx.doi.org/10.1111/j.1475-2743.2009.00238.x.
http://dx.doi.org/10.1111/j.1475-2743.20... ) and low natural fertility (Table 1).

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Table 1
Chemical analysis of soil in the experimental area, in depths of 0 - 10 and 10 - 20 cm.

We tested 4 perennial leguminous species, 2 of which have a higher quality residue, i.e., Leucaena leucocephala (Leucaena) and Gliricidia sepium (Gliricidia), and 2 that produce a lower quality residue, i.e., Clitoria fairchildiana (Clitoria) and Acacia mangium (Acacia) (Vanlauwe et al. 1997Vanlauwe, B., Diels, F., Sanginga, N. and Merckx, R. (1997). Residue quality and decomposition: an unsteady relationship? In G. Cadisch, and K. E. Giller (Eds.), Driven by Nature: Plant Litter Quality and Decomposition (p. 157-166). Wallingford: CAB International.; Aguiar et al. 2010Aguiar, A. C. F., Bicudo, S. J., Costa Sobrinho, J. R. S., Martins, A. L. S., Coelho, K. P. and Moura, E. G. (2010). Nutrient recycling and physical indicators of an alley cropping system in a sandy loam soil in the pre-Amazon region of Brazil. Nutrient Cycling in Agroecosystems, 86, 189-198. http://dx.doi.org/10.1007/s10705-009-9283-6
http://dx.doi.org/10.1007/s10705-009-928... ). The quality of the legume residue was determined based on its relative nutrient (especially N), lignin, and polyphenol contents (Tian et al. 1995Tian, G., Brussaard, L. and Kang, B. (1995). An index for assessing the quality of plant residues and evaluating their effects on soil and crop in the (sub-) humid tropics. Applied Soil Ecology, 2, 25-32. http://dx.doi.org/10.1016/0929-1393(94)00033-4.
http://dx.doi.org/10.1016/0929-1393(94)0... ). The experiment was designed as a 6 × 2 factorial (a combination of 4 legume species versus 2 N levels) with 4 replications in a randomized block design and the following treatments: Gliricidia + Acacia (GA), Gliricidia + Leucaena (GL), Gliricidia + Clitoria (GC), Leucaena + Acacia (LA), Leucaena + Clitoria (LC), and a control without legumes. The chemical characteristics of the legumes are presented in Table 2.

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Table 2
Chemical characteristics of the leguminous.

The no-tillage alley cropping system was established in 2002 with legumes planted at a 0.05-m spacing in an eastern-western row orientation to maximize light absorption by the crops. Double rows were used such that each 5 × 4 m plot received 2 types of residues, i.e., low- and high-quality residues that resulted from the combination of 2 legumes (Figure 1). Since 2003, maize (Zea mays L.) was grown during the rainy season.

Figure 1
Diagram of an experimental plot showing a single row oftrees, with and without nitrogen (N).

The first pruning of legumes was performed in 2004 and was continued in the following years. Pruning was performed annually to 0.5 m above ground level, and a second pruning was performed when needed to avoid shading the annual crop in the alleys. The green biomass produced annually by the legumes was similar (± 10 t·ha^–1) and evenly distributed over the respective plots. The weeds were controlled by using hand hoeing. The residues did not produce any differences in the density and richness of the weed species, as reported by Moura et al. (2014)Moura, E. G., Marques, E. S., Silva, T. M. B., Piedade, A. and Aguiar, A. C. F. (2014). Interactions among leguminous trees, crops and weeds in a no-till alley cropping system. International Journal of Plant Production, 8, 441-456..

Pro-vitamin-biofortified cassava (cultivar BRS Dourada) was planted during the rainy season in February 2012 between rows of leguminous plants in plots measuring 5.0 m × 4.0 m. Cassava rows were spaced 1 m apart with 0.50 m between individual plants.

Cassava was fertilized at planting with 40 kg·ha^–1 of K₂O and 70 kg·ha^–1 of P₂O₅ applied as potassium chloride and triple superphosphate, respectively. In addition, 100 kg·ha–1 of urea N was applied twice in March 2012 and 2013 to the N treatments. The cassava was harvested in October 2013 after 20 months growth.

Soil sampling and analysis

Prior to planting the cassava, soil samples were collected from the 0 – 20 cm layer using a heavy duty auger. The soil samples were analyzed for pH (0.01 M CaCl₂ suspension, 1:2.5 soil/solution, v/v), organic carbon (Walkley-Black), P and exchangeable K, Ca, Mg (resin), and H + Al (SMP method) in accordance with the standard methods (van Raij et al. 2001Van Raij, B., Andrade, J. C., Cantarella, H. and Quaggio, J. A. (2001). Análise química para avaliação da fertilidade de solos tropicais. Campinas: Instituto Agronômico.). The cation exchange capacity (CEC) was determined as the sum of K, Ca, Mg, H, and Al. The sum of bases (SB) was calculated as K + Ca + Mg, and the base saturation percentage (BSP), as SB/CEC × 100.

The following yield parameters were measured on 15 cassava plants per plot: shoot weight (t·ha^–1), number of roots per plant, root weight (g), and total root production (t·ha^–1).

Three cassava roots were used for the following analyses:

Proximate composition: cassava roots were peeled and crushed for determination of the moisture, and ash contents and were dried at 50°C for 24 h for the determination of the lipid and protein contents. The moisture, ash and protein contents (AOAC 2005Association of Official Analytical Chemists (2005). Official Methods of Analysis. 16th ed. Washington: AOAC International.), and lipids (Bligh and Dyer 1959Bligh, E. G. and Dyer, W. J. (1959). A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology, 37, 911-917. http://dx.doi.org/10.1139/o59-099.
http://dx.doi.org/10.1139/o59-099... ) were measured. The total carbohydrate content was estimated by subtracting 100 from the percent moisture, ash, lipid, and protein contents. Proximate composition is a partitioning of compounds in a feed into categories based on the chemical properties of the compounds, which are expressed as the content (%) in the feed, respectively
Starch content: cassava roots were dried in an oven at 50 °C for 24 h, and enzymatic hydrolysis was conducted (AOAC 2005Association of Official Analytical Chemists (2005). Official Methods of Analysis. 16th ed. Washington: AOAC International.). Root samples (100 mg) were added to 0.2 mL of 80% ethanol, 3 mL of 0.2 M sodium phosphate buffer (pH 6.8), and 100 µL of thermostable α-amylase. The mixture was placed in a water bath at 95 °C for 5 min. Then, 4 mL of 200 mM sodium acetate buffer (pH 4.5) and 100 µL of amyloglucosidase were added. The mixture remained at 50 °C in a water bath with stirring for 30 min. The contents were transferred to a 100-mL flask, filled to volume with water, and filtered through filter paper. The glucose content was determined using a Glucox 500 kit and converted to starch by multiplying it by a factor of 0.9.
Mineral content: cassava roots were peeled, crushed, and dried at 50 °C for 24 h. Samples (1 g) were digested at 200 °C for 1 h in 10 mL of nitric acid solution: perchloric acid (2:1) (AOAC 2005Association of Official Analytical Chemists (2005). Official Methods of Analysis. 16th ed. Washington: AOAC International.). After transferring the samples to a 50 mL volumetric flask that was then filled to volume with water, the elements were analyzed using inductively coupled plasma-optical emission spectroscopy (ICP Optical Emission Spectrometer, Varian, Melbourne, Australia) and ICP Expert II software (Varian, Melbourne, Australia). The equipment operating conditions were as follows: plasma power of 1.0 kW; auxiliary gas (air) flow of 1.5 L∙min^–1; nebulizer pressure of 200 kPa, and plasma flow of 15.0 L∙min^–1.
• Carotenoid and pro-vitamin A contents: a carotenoid analysis was conducted with the protection from light, the avoidance of high temperatures, and the use of antioxidants (Rodriguez-Amaya and Kimura 2004Rodriguez-Amaya, D. B. and Kimura, M. (2004). HarvestPlus Handbook for Carotenoid Analysis. Washington: IFPRI, CIAT.). Briefly, the carotenoids from 20 g of cassava, to which butylated hydroxytoluene (0.1%) was added to minimize oxidation, were extracted 4 times with cold acetone using a Polytron homogenizer until the residue lacked color completely. The pigments were transferred from the acetone to petroleum ether. An aliquot of carotenoid extract was properly diluted, and the total carotenoids were determined spectrophotometrically at an absorbance of 450 nm using a UV-visible recording pectrophotometer (Lambda 25 Perkin Elmer) as well as the absorption coefficient of β-carotene (2592).

The extract was evaporated under N, dissolved in 1 mL of acetone, filtered through a 0.45 μm polytetrafluoroethylene syringe filter (Millipore), and then 10 μL was automatically injected into the high-performance liquid chromatography (HPLC) system. The HPLC-PAD (high-performance liquid chromatography-photodiode array detector) analysis was carried out using a ProStar Varian separation module equipped with a quaternary pump and autosampler injector controlled by a Galaxie workstation. A monomeric C₁₈ column (Waters Spherisorb ODS-2; 3 μm; 150 × 4.6 mm) was used. The mobile phase consisted of acetonitrile (containing 0.05% of triethylamine), methanol, and ethyl acetate in proportions of 95:5:0 to 93:7:0 for 7 min, then 60:20:20 between 20 and 38 min, and finally 95:5:0 until the end of the run (42 min). The flow rate was 0.5 mL∙min^–1.

Carotenoid detection occurred at the wavelengths that corresponded to the maximum absorption of the carotenoids in the mobile phase. The carotenoids were identified according to: (a) their retention time, using carotenoid standards analyzed under the same chromatographic conditions; (b) their maximum absorbed wavelength (λmax) on a diode array detector; (c) their fine structure — % III/II, which is expressed as the ratio between the peak height of the longest-wavelength absorption band (III) and the middle absorption peak, generally λmax (II), which assumes the minimum between the 2 peaks as the baseline, multiplied by 100; and (d) the presence (or absence) of the cis peak between 340 and 346 nm.

The concentration of each carotenoid identified was measured using external standardization. Standard curves were prepared using 6 different concentration points for lutein (r = 0.999), β-carotene (r = 0.999), zeaxanthin (r = 0.999), and ζ-carotene (r = 0.999). The standards were obtained from the DSM Nutritional Product. Cis β-cryptoxanthin was estimated using β-carotene standard curves. The pro-vitamin A was calculated according to the new conversion factor specified by the Institute of Medicine Food and Nutrition Board (IOM 2001Institute of Medicine Food and Nutrition Board (2001). Dietary reference intakes: for vitamin a, vitamin k, arsenic, boron, cromium, copper, iodine, iron, manganese, molybdenium, nickel, silicon, vanadium and zinc. Washington: National Academy Press.), where 12 μg of β-carotene and 24 μg of cis β-carotene and β-cryptoxanthin correspond to 1 retinol activity equivalent (RAE).

Statistical analysis

The data were subjected to analysis of variance with 2 factors followed by Duncan’s multiple range test at 5%. Statistical analysis was performed using Statistica, version 10.0.

RESULTS AND DISCUSSION

The residues had a greater effect than the N, which did not influence any yield component when used alone (Table 3). There was large variation in the growth of cassava, and the residues had a marked effect on the dry matter production of the shoot. Except for LC and GA, all other combinations of residues were superior to the N treatment without residue. There was no significant difference between the N treatments in bare soil and the control. The LC + N treatment resulted in a shoot dry weight that was superior to the other treatments except for GC + N and GL + N. In the GL, LA, and GA treatments, there was no significant increase in dry matter with the use of N. The GA + N treatment resulted in a lower number of roots compared with the GC + N as well as LC + N treatments and was not significantly different from the control. The number of roots in the GC + N treatment was twice that of the control. The differences in the average root weight were small; the bare soil treatment with N had a lower root weight than GL + N, LC + N, GA + N, GL, and LA; other treatments were intermediate in their effect on root weight. The GL treatment was superior to the GC + N, GA + N, LC, GC, and GA treatments in increasing root production, even without N. The GC and LC treatments without N did not increase root production compared with the control. The addition of N increased the root production only in GC and LC treatments.

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Table 3
Yields components for the different treatments of biofortified cassava.

The low inorganic N agronomic efficiency (∆ productivity/N applied) in bare soil, which was verified in this experiment, has been reported as a significant problem in tropical agriculture (Moura et al. 2009Moura, E. G., Moura, N. G., Marques, E. S., Pinheiro, K. M., Costa Sobrinho, J. R. S. and Aguiar, A. C. F. (2009). Evaluating chemical and physical quality indicators for a structurally fragile tropical soil. Soil Use and Management, 25, 368-375. http://dx.doi.org/10.1111/j.1475-2743.2009.00238.x.
http://dx.doi.org/10.1111/j.1475-2743.20... ). However, the surface application of residues improves the condition of soil rootability by increasing the depth layer for root growth, which is associated with greater water retention, root penetration, and nutrient uptake. It is worth highlighting that the combination of Gliricidia plus Leucaena, both high-quality residues, was superior for root yield. This indicates that the greater availability of organic N provided by faster decomposition of these legumes at the beginning of the rainy season was more important than the durability of the soil cover for root production. By contrast, the treatments with Clitoria (GC and LC) were more dependent on the use of N due to the low capacity of this species to provide the nutrient (Moura et al. 2010Moura, E. G., Serpa, S. S., Santos, J. G. D., Costa Sobrinho, J. R. S. and Aguiar, A. C. F. (2010). Nutrient use efficiency in alley cropping systems in the Amazonian periphery. Plant and Soil, 335, 363-371. http://dx.doi.org/10.1007/s11104-010-0424-0.
http://dx.doi.org/10.1007/s11104-010-042... ).

The variations in the proximate composition were small (Table 4). The roots of the control plots had a higher moisture content than the GC + N and BS + N treatments. The other treatments did not show significant differences. The lipid content in the GC + N treatment was higher than in the other treatments except for LC, BS + N, and the control. In addition, the protein content was higher in GC + N than in LC + N, LA + N, and the other treatments without N. Further, higher starch contents were measured in the GC + N and BS + N treatments, but the GL + N one was superior to all other treatments except for LC with and without N. There were no significant treatment effects on the ash and carbohydrate contents.

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Table 4
Proximate composition for the different treatments of biofortified cassava.

The residues affected the mineral nutrient content of cassava roots (Table 5). The highest calcium (Ca) and magnesium (Mg) contents were measured in control plots; however, the GA + N treatment exhibited higher Ca contents compared with the other treatments. The potassium content varied with treatment and was higher in GC + N than in LA + N, LC + N, LA, GL, BS + N, and the control. The iron content was higher in GL + N than in the treatments without residues, BS + N, LA + N, and LC + N. The iodine content decreased in the following order: GL + N = GC + N > LA + N = LC + N = LA = GA. There was no treatment effect on the P or Zn contents.

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Table 5
Concentrations of minerals for the different treatments of biofortified cassava.

The Ca and K contents varied with residue treatment. Vigorous growth of root systems is required to intercept and absorb these nutrients, and, therefore, Ca and K absorption is highly dependent on root activity (Sawyer and Mallarino 2002Sawyer, J. E. and Mallarino, A. P. (2002). Corn leaf potassium deficiency symptoms. In The Integrated Crop Management Newsletter. Iowa State University Extension. IC-488.). However, other factors in addition to soil rootability and nutrient availability must have contributed to the higher Ca content in GA + N and the higher K content in GC + N. The combined use of 2 allelopathic genera, such as Leucaena and Acacia in LA treatment, may decrease the nutrient uptake of sensitive crops and eliminate the positive effects of the trees on nutrient availability and soil rootability (Moura et al. 2014Moura, E. G., Marques, E. S., Silva, T. M. B., Piedade, A. and Aguiar, A. C. F. (2014). Interactions among leguminous trees, crops and weeds in a no-till alley cropping system. International Journal of Plant Production, 8, 441-456.). Therefore, the inclusion of a non-allelopathic (e.g., a native such as Clitoria) genus with additional desirable characteristics for residue mixtures could be a good potential strategy. This approach would help to mitigate the negative effect of allelopathic genera such as Leucaena and Acacia, where phenolic acids are present at very high concentrations and can alter the rate at which ions are absorbed by plants (Zhang et al. 2010Zhang, L., Chen, J., Wang, Y., Wu, D. and Xu, M. (2010). Phenolic extracts from Acacia mangium bark and their antioxidant activities. Molecules, 15, 3567-3577. http://dx.doi.org/10.3390/molecules15053567.
http://dx.doi.org/10.3390/molecules15053... ). One mechanism through which plant growth is inhibited by this class of allelochemicals may be an alteration in membrane permeability (Glass and Dunlop 1974Glass, A. D. M. and Dunlop, J. (1974). Influence of phenolic acids on ion uptake. IV. Depolarization of membrane potentials. Plant Physiology, 54, 855-858.).

The low Fe and Zn contents in all treatments suggest the importance of a strategy for enhancing the uptake of these nutrients by crops in the infertile soils of the humid tropics. These nutrients can be chelated by soluble organic matter compounds during the decomposition process of residues. For example, organic matter containing Zn must undergo mineralization before it becomes available for plant uptake (Tarighi et al. 2012Tarighi, H., Majidian, M., Baghaie, A.H. and Gomarian, M. (2012). Zinc availability of two wheat cultivars in soil amended with organic and inorganic Zn sources. African Journal of Biotechnology, 11, 436-443. http://dx.doi.org/10.5897/AJB11.1839.
http://dx.doi.org/10.5897/AJB11.1839... ). The higher contents of iron in the GL + N treatment may be related to the faster decomposition process of this high-quality residue.

Due to their low concentration levels, the differences in lipid and protein contents in this experiment are not biologically relevant and therefore could not significantly modify root quality. In addition, the variation in lipid content, i.e., lower contents in the more productive treatments, appears to be related to the differences in productivity rather than the effect of the treatments, likely due to a dilution effect.

The inorganic N was more important than the residue for increasing the protein content in the roots; therefore, the accumulated protein (97.7 kg∙ha^–1) in GL + N was superior to the treatments without inorganic N (data not showed). When a plant is presented with a large amount of N, the protein production increases and carbohydrate production is reduced; however, when N levels limit photosynthesis, proteins are not fully used in the synthesis of organic N compounds, and sugars accumulate (Worthington 2001Worthington, V. (2001). Nutritional quality of organic versus conventional fruits, vegetables and grains. Journal of Alternative and Complementary Medicine, 7, 161-173.). The higher content of starch in the GC + N treatment can be attributed to the greater capacity of cassava to take up potassium (K). Because cassava is a high carbohydrate producer, it requires a large amount of K, which has a special role in carbohydrate synthesis and translocation. Abundant uptake of K favors photosynthesis. The translocation of photosynthates from the green parts of the plant (leaf) to the storage root is of utmost importance for the building up of storage organs (tubers) (Susan John et al. 2010Susan John, K., Suja, G., Sheela, M. N. and Ravindran, C. S. (2010). Potassium: The Key Nutrient for Cassava Production, Tuber Quality and Soil Productivity - An Overview. Journal of Root Crops, 36, 132-144.).

In the biofortified cassava genotype (BRS Dourada), trans β-carotene was the predominant isomer in all treatments and the major isomer with vitamin A activity (Figure 2). The carotenoid content was modified by the application of residues (Table 6). The highest total carotenoid content was measured in the roots of the GC + N and LC treatments.

Figure 2
Chromatogram of the carotenoids of the control.

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Table 6
Contents of carotenoids and pro-vitamin A for the different treatments of biofortified cassava.

GC + N was superior in terms of cis β-cryptoxanthin, trans β-carotene, and (13 cis) β-carotene, whereas LC was superior in terms of cis β-cryptoxanthin, trans ζ-carotene, (9 cis) β-carotene, and (13 cis) β-carotene. The highest pro-vitamin A content was measured in GC + N, followed by LC and the remaining treatments.

The highest carotene and pro-vitamin A contents were measured in the GC + N treatment that also contained a high protein content, which may be attributed to the protein required for the accumulation of carotenoids in cassava. Genetic studies on total carotenoid and protein contents indicate a highly significant and positive correlation between root protein in the plastid fraction and total carotenoid content (Carvalho et al. 2011Carvalho, L. J. C. B., Vieira, E. A., Fialho, J. F. and Souza, C. R. B. (2011). A genomic assisted breeding program for cassava to improve nutritional quality and industrial traits of storage root. Crop Breeding and Applied Biotechnology, 11, 289-296. http://dx.doi.org/10.1590/S1984-70332011000400001.
http://dx.doi.org/10.1590/S1984-70332011... ). The current experiment indicated that changes in protein content caused by environmental factors such as soil fertility maintain this relationship.

CONCLUSION

In soils of low natural fertility in the humid tropics, the quality and yield of cassava can be modified with residues of leguminous trees; however, N fertilizer does not produce the same effect. In addition, to increase root production, the use of combined high-quality residues with the fastest release of N (GL) was superior to residues with slow decomposition rates (GA and GC). The increase in protein content was dependent on readily available N and influenced the carotenoid content. The allelopathic effect of exotic genera such as Leucaena and Acacia, especially when combined, can decrease the uptake of nutrients such as potassium and therefore reduce starch accumulation. In soil derived from sedimentary clastic rock with low contents of iron and zinc, a strategy to increase the contents of these nutrients in cassava remains to be discovered.

ACKNOWLEDGEMENTS

The authors acknowledge the National Council for Scientific and Technological Development (CNPq), the Coordination for the Improvement of Higher Education Personnel (CAPES), and the Foundation for Research and Scientific and Technological Development of Maranhão (FAPEMA), Brazil, for the financial support.

REFERENCES

Aguiar, A. C. F., Bicudo, S. J., Costa Sobrinho, J. R. S., Martins, A. L. S., Coelho, K. P. and Moura, E. G. (2010). Nutrient recycling and physical indicators of an alley cropping system in a sandy loam soil in the pre-Amazon region of Brazil. Nutrient Cycling in Agroecosystems, 86, 189-198. http://dx.doi.org/10.1007/s10705-009-9283-6
» http://dx.doi.org/10.1007/s10705-009-9283-6
Aguiar, A. C. F., Freitas, I. C., Carvalho, C. S., Monroe, P. H. M. and Moura, E. G. (2011). Efficiency of an agrosystem designed for family farming in the pre-Amazon region. Renewable Agriculture and Food Systems, 26, 24-30. http://dx.doi.org/10.1017/S1742170510000396
» http://dx.doi.org/10.1017/S1742170510000396
Association of Official Analytical Chemists (2005). Official Methods of Analysis. 16th ed. Washington: AOAC International.
Bligh, E. G. and Dyer, W. J. (1959). A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology, 37, 911-917. http://dx.doi.org/10.1139/o59-099
» http://dx.doi.org/10.1139/o59-099
Burns, A. E., Gleadow, R. M., Zacarias, A. M., Cuambe, C. E., Miller, R. E. and Cavagnaro, T. R. (2012). Variations in the chemical composition of cassava (Manihot esculenta Crantz) leaves and roots as affected by genotypic and environmental variation. Journal of Agricultural and Food Chemistry, 60, 4946-4956. http://dx.doi.org/10.1021/jf2047288
» http://dx.doi.org/10.1021/jf2047288
Carvalho, L. J. C. B., Vieira, E. A., Fialho, J. F. and Souza, C. R. B. (2011). A genomic assisted breeding program for cassava to improve nutritional quality and industrial traits of storage root. Crop Breeding and Applied Biotechnology, 11, 289-296. http://dx.doi.org/10.1590/S1984-70332011000400001
» http://dx.doi.org/10.1590/S1984-70332011000400001
Glass, A. D. M. and Dunlop, J. (1974). Influence of phenolic acids on ion uptake. IV. Depolarization of membrane potentials. Plant Physiology, 54, 855-858.
Institute of Medicine Food and Nutrition Board (2001). Dietary reference intakes: for vitamin a, vitamin k, arsenic, boron, cromium, copper, iodine, iron, manganese, molybdenium, nickel, silicon, vanadium and zinc. Washington: National Academy Press.
Kaweewong, J., Kongkeaw, T., Tawornprek, S., Yampracha, S. and Yost, R. (2013). Nitrogen requirements of cassava in selected soils of Thailand. Journal of Agriculture and Rural Development in the Tropics and Subtropics, 114, 13-19.
Montagnac, J. A., Davis, C. R. and Tanumihardjo, S. A. (2009). Nutritional value of cassava for use as a staple food and recent advances for improvement. Comprehensive Reviews in Food Science and Food Safety, 8, 181-194. http:/dx.doi.org/10.1111/j.1541-4337.2009.00077.x.
» http:/dx.doi.org/10.1111/j.1541-4337.2009.00077.x
Moura, E. G., Moura, N. G., Marques, E. S., Pinheiro, K. M., Costa Sobrinho, J. R. S. and Aguiar, A. C. F. (2009). Evaluating chemical and physical quality indicators for a structurally fragile tropical soil. Soil Use and Management, 25, 368-375. http://dx.doi.org/10.1111/j.1475-2743.2009.00238.x
» http://dx.doi.org/10.1111/j.1475-2743.2009.00238.x
Moura, E. G., Serpa, S. S., Santos, J. G. D., Costa Sobrinho, J. R. S. and Aguiar, A. C. F. (2010). Nutrient use efficiency in alley cropping systems in the Amazonian periphery. Plant and Soil, 335, 363-371. http://dx.doi.org/10.1007/s11104-010-0424-0
» http://dx.doi.org/10.1007/s11104-010-0424-0
Moura, E. G., Monroe, P. H. M., Coelho, M.J.A., Costa Sobrinho, J.R.S. and Aguiar, A.C.F. (2013). Effectiveness of calcined rock phosphate and leucaena prunings as a source of nutrients for maize in a tropical soil. Biological Agriculture & Horticulture, 29, 132-144. http://dx.doi.org/10.1080/01448765.2013.781486
» http://dx.doi.org/10.1080/01448765.2013.781486
Moura, E. G., Marques, E. S., Silva, T. M. B., Piedade, A. and Aguiar, A. C. F. (2014). Interactions among leguminous trees, crops and weeds in a no-till alley cropping system. International Journal of Plant Production, 8, 441-456.
Ngaboyisonga, C., Njoroge, K., Kirubi, D. and Githiri, S. M. (2012). Quality protein maize under low N and drought environments: endosperm modification, protein and tryptophan concentrations in grains. Agricultural Journal, 7, 327-338. http://dx.doi.org/10.3923/aj.2012.327.338
» http://dx.doi.org/10.3923/aj.2012.327.338
Van Raij, B., Andrade, J. C., Cantarella, H. and Quaggio, J. A. (2001). Análise química para avaliação da fertilidade de solos tropicais. Campinas: Instituto Agronômico.
Rodriguez-Amaya, D. B. and Kimura, M. (2004). HarvestPlus Handbook for Carotenoid Analysis. Washington: IFPRI, CIAT.
Sawyer, J. E. and Mallarino, A. P. (2002). Corn leaf potassium deficiency symptoms. In The Integrated Crop Management Newsletter. Iowa State University Extension. IC-488.
Susan John, K., Suja, G., Sheela, M. N. and Ravindran, C. S. (2010). Potassium: The Key Nutrient for Cassava Production, Tuber Quality and Soil Productivity - An Overview. Journal of Root Crops, 36, 132-144.
Tarighi, H., Majidian, M., Baghaie, A.H. and Gomarian, M. (2012). Zinc availability of two wheat cultivars in soil amended with organic and inorganic Zn sources. African Journal of Biotechnology, 11, 436-443. http://dx.doi.org/10.5897/AJB11.1839
» http://dx.doi.org/10.5897/AJB11.1839
Tian, G., Brussaard, L. and Kang, B. (1995). An index for assessing the quality of plant residues and evaluating their effects on soil and crop in the (sub-) humid tropics. Applied Soil Ecology, 2, 25-32. http://dx.doi.org/10.1016/0929-1393(94)00033-4
» http://dx.doi.org/10.1016/0929-1393(94)00033-4
Vanlauwe, B., Diels, F., Sanginga, N. and Merckx, R. (1997). Residue quality and decomposition: an unsteady relationship? In G. Cadisch, and K. E. Giller (Eds.), Driven by Nature: Plant Litter Quality and Decomposition (p. 157-166). Wallingford: CAB International.
Worthington, V. (2001). Nutritional quality of organic versus conventional fruits, vegetables and grains. Journal of Alternative and Complementary Medicine, 7, 161-173.
Zhang, L., Chen, J., Wang, Y., Wu, D. and Xu, M. (2010). Phenolic extracts from Acacia mangium bark and their antioxidant activities. Molecules, 15, 3567-3577. http://dx.doi.org/10.3390/molecules15053567
» http://dx.doi.org/10.3390/molecules15053567

Publication Dates

Publication in this collection
29 May 2017
Date of issue
Jul-Sept 2017

History

Received
09 Jan 2016
Accepted
07 Oct 2016

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

[1] Aguiar, A. C. F., Bicudo, S. J., Costa Sobrinho, J. R. S., Martins, A. L. S., Coelho, K. P. and Moura, E. G. (2010). Nutrient recycling and physical indicators of an alley cropping system in a sandy loam soil in the pre-Amazon region of Brazil. Nutrient Cycling in Agroecosystems, 86, 189-198. http://dx.doi.org/10.1007/s10705-009-9283-6
» http://dx.doi.org/10.1007/s10705-009-9283-6

[2] Aguiar, A. C. F., Freitas, I. C., Carvalho, C. S., Monroe, P. H. M. and Moura, E. G. (2011). Efficiency of an agrosystem designed for family farming in the pre-Amazon region. Renewable Agriculture and Food Systems, 26, 24-30. http://dx.doi.org/10.1017/S1742170510000396
» http://dx.doi.org/10.1017/S1742170510000396

[3] Association of Official Analytical Chemists (2005). Official Methods of Analysis. 16th ed. Washington: AOAC International.

[4] Bligh, E. G. and Dyer, W. J. (1959). A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology, 37, 911-917. http://dx.doi.org/10.1139/o59-099
» http://dx.doi.org/10.1139/o59-099

[5] Burns, A. E., Gleadow, R. M., Zacarias, A. M., Cuambe, C. E., Miller, R. E. and Cavagnaro, T. R. (2012). Variations in the chemical composition of cassava (Manihot esculenta Crantz) leaves and roots as affected by genotypic and environmental variation. Journal of Agricultural and Food Chemistry, 60, 4946-4956. http://dx.doi.org/10.1021/jf2047288
» http://dx.doi.org/10.1021/jf2047288

[6] Carvalho, L. J. C. B., Vieira, E. A., Fialho, J. F. and Souza, C. R. B. (2011). A genomic assisted breeding program for cassava to improve nutritional quality and industrial traits of storage root. Crop Breeding and Applied Biotechnology, 11, 289-296. http://dx.doi.org/10.1590/S1984-70332011000400001
» http://dx.doi.org/10.1590/S1984-70332011000400001

[7] Glass, A. D. M. and Dunlop, J. (1974). Influence of phenolic acids on ion uptake. IV. Depolarization of membrane potentials. Plant Physiology, 54, 855-858.

[8] Institute of Medicine Food and Nutrition Board (2001). Dietary reference intakes: for vitamin a, vitamin k, arsenic, boron, cromium, copper, iodine, iron, manganese, molybdenium, nickel, silicon, vanadium and zinc. Washington: National Academy Press.

[9] Kaweewong, J., Kongkeaw, T., Tawornprek, S., Yampracha, S. and Yost, R. (2013). Nitrogen requirements of cassava in selected soils of Thailand. Journal of Agriculture and Rural Development in the Tropics and Subtropics, 114, 13-19.

[10] Montagnac, J. A., Davis, C. R. and Tanumihardjo, S. A. (2009). Nutritional value of cassava for use as a staple food and recent advances for improvement. Comprehensive Reviews in Food Science and Food Safety, 8, 181-194. http:/dx.doi.org/10.1111/j.1541-4337.2009.00077.x.
» http:/dx.doi.org/10.1111/j.1541-4337.2009.00077.x

[11] Moura, E. G., Moura, N. G., Marques, E. S., Pinheiro, K. M., Costa Sobrinho, J. R. S. and Aguiar, A. C. F. (2009). Evaluating chemical and physical quality indicators for a structurally fragile tropical soil. Soil Use and Management, 25, 368-375. http://dx.doi.org/10.1111/j.1475-2743.2009.00238.x
» http://dx.doi.org/10.1111/j.1475-2743.2009.00238.x

[12] Moura, E. G., Serpa, S. S., Santos, J. G. D., Costa Sobrinho, J. R. S. and Aguiar, A. C. F. (2010). Nutrient use efficiency in alley cropping systems in the Amazonian periphery. Plant and Soil, 335, 363-371. http://dx.doi.org/10.1007/s11104-010-0424-0
» http://dx.doi.org/10.1007/s11104-010-0424-0

[13] Moura, E. G., Monroe, P. H. M., Coelho, M.J.A., Costa Sobrinho, J.R.S. and Aguiar, A.C.F. (2013). Effectiveness of calcined rock phosphate and leucaena prunings as a source of nutrients for maize in a tropical soil. Biological Agriculture & Horticulture, 29, 132-144. http://dx.doi.org/10.1080/01448765.2013.781486
» http://dx.doi.org/10.1080/01448765.2013.781486

[14] Moura, E. G., Marques, E. S., Silva, T. M. B., Piedade, A. and Aguiar, A. C. F. (2014). Interactions among leguminous trees, crops and weeds in a no-till alley cropping system. International Journal of Plant Production, 8, 441-456.

[15] Ngaboyisonga, C., Njoroge, K., Kirubi, D. and Githiri, S. M. (2012). Quality protein maize under low N and drought environments: endosperm modification, protein and tryptophan concentrations in grains. Agricultural Journal, 7, 327-338. http://dx.doi.org/10.3923/aj.2012.327.338
» http://dx.doi.org/10.3923/aj.2012.327.338

[16] Van Raij, B., Andrade, J. C., Cantarella, H. and Quaggio, J. A. (2001). Análise química para avaliação da fertilidade de solos tropicais. Campinas: Instituto Agronômico.

[17] Rodriguez-Amaya, D. B. and Kimura, M. (2004). HarvestPlus Handbook for Carotenoid Analysis. Washington: IFPRI, CIAT.

[18] Sawyer, J. E. and Mallarino, A. P. (2002). Corn leaf potassium deficiency symptoms. In The Integrated Crop Management Newsletter. Iowa State University Extension. IC-488.

[19] Susan John, K., Suja, G., Sheela, M. N. and Ravindran, C. S. (2010). Potassium: The Key Nutrient for Cassava Production, Tuber Quality and Soil Productivity - An Overview. Journal of Root Crops, 36, 132-144.

[20] Tarighi, H., Majidian, M., Baghaie, A.H. and Gomarian, M. (2012). Zinc availability of two wheat cultivars in soil amended with organic and inorganic Zn sources. African Journal of Biotechnology, 11, 436-443. http://dx.doi.org/10.5897/AJB11.1839
» http://dx.doi.org/10.5897/AJB11.1839

[21] Tian, G., Brussaard, L. and Kang, B. (1995). An index for assessing the quality of plant residues and evaluating their effects on soil and crop in the (sub-) humid tropics. Applied Soil Ecology, 2, 25-32. http://dx.doi.org/10.1016/0929-1393(94)00033-4
» http://dx.doi.org/10.1016/0929-1393(94)00033-4

[22] Vanlauwe, B., Diels, F., Sanginga, N. and Merckx, R. (1997). Residue quality and decomposition: an unsteady relationship? In G. Cadisch, and K. E. Giller (Eds.), Driven by Nature: Plant Litter Quality and Decomposition (p. 157-166). Wallingford: CAB International.

[23] Worthington, V. (2001). Nutritional quality of organic versus conventional fruits, vegetables and grains. Journal of Alternative and Complementary Medicine, 7, 161-173.

[24] Zhang, L., Chen, J., Wang, Y., Wu, D. and Xu, M. (2010). Phenolic extracts from Acacia mangium bark and their antioxidant activities. Molecules, 15, 3567-3577. http://dx.doi.org/10.3390/molecules15053567
» http://dx.doi.org/10.3390/molecules15053567

Depth (cm) 0 - 10	Bare soil	Leucaena + Clitoria	Gliricidia + Leucaena	Leucaena + Acacia	Gliricidia + Acacia	Gliricidia + Clitoria
pH (CaCl₂)	5.20 ± 0.22¹ 1 Mean plus standard error.	5.03 ± 0.04	5.23 ± 0.15	4.81 ± 0.34	4.66 ± 0.18	5.45 ± 0.39
Al³+ (mmol_c∙dm^-3)	-	-	-	-	-	-
Ca²+ (mmol_c∙dm^-3)	9.00 ± 0.00	13.50 ± 0.58	11.25 ± 0.96	11.50 ± 0.58	10.75 ± 1.26	11.50 ± 1.00
Potential acidity (mmol_c∙dm^-3)	15.50 ± 1.00	25.58 ± 0.69	22.75 ± 2.22	28.50 ± 3.11	30.75 ± 9.22	15.75 ± 1.26
Sum of bases (mmol_c∙dm^-3)	1724 ± 0.04	22.23 ± 0.05	19.27 ± 0.01	20.23 ± 0.01	15.23 ± 0.02	20.21 ± 0.05
Base saturation percentage (%)	50.09 ± 0.44	45.83 ± 0.36	45.46 ± 0.40	40.84 ± 0.36	31.43 ± 0.15	53.21 ± 0.83
Depth (cm) 10 - 20	Bare soil	*Leucaena + Clitoria*	*Gliricidia + Leucaena*	*Leucaena + Acacia*	*Gliricidia + Acacia*	*Gliricidia + Clitoria*
pH (CaCl₂)	4.18 ± 0.11	4.20 ± 0.04	4.19 ± 0.16	4.10 ± 0.10	3.99 ± 0.13	4.26 ± 0.09
Al³+ (mmol_c∙dm^-3)	3.13 ± 0.25	3.57 ± 0.08	3.45 ± 0.08	3.75 ± 0.11	6.40 ± 0.27	2.57 ± 0.08
Ca²+ (mmol_c∙dm^-3)	3.00 ± 0.00	3.02 ± 0.00	3.00 ± 0.00	3.00 ± 0.00	3.97 ± 0.05	3.00 ± 0.01
Potential acidity (mmol_c∙dm^-3)	28.75 ± 1.50	36.00 ± 0.00	33.25 ± 0.50	33.25 ± 0.96	3700 ± 2.16	29.50 ± 1.00
Sum of bases (mmol_c∙dm^-3)	6.10 ± 0.04	6.15 ± 0.04	6.02 ± 0.03	4.12 ± 0.03	715 ± 0.03	6.15 ± 0.05
Base saturation percentage (%)	14.41 ± 0.70	14.27 ± 0.27	13.29 ± 0.24	13.07 ± 1.71	13.22 ± 1.57	14.40 ± 0.42

		C/N	N	P	K	Ca	Mg
	kg∙ha^-1 of dry matter
Leucaena		11.48	43.56	2.71	5.72	3.20	3.69
Gliricidia		13.51	3701	1.48	4.62	3.36	2.33
Clitoria		18.38	27.21	3.15	4.89	3.75	2.09
Acacia		23.45	21.32	2.57	5.22	2.99	2.99

	GL + N	LA + N	LC + N	GC + N	GA + N	GL	LA	LC	GC	GA	BS + N	Control
Weight of shoots (t∙ha^-1)	22.3abc	19.7bcd	26.6a	23.3ab	16.1def	20.1bcd	17.6cde	10.9fg	16.2def	13.1efg	8.3gh	5.4h
Number of roots per plant	5.2abc	5.2abc	5.3ab	5.5a	3.8cde	4.8abc	4.7abc	4.0bcd	3.8cde	3.3de	3.1de	2.6e
Rootsweight(g)	334.4a	268.6ab	335.7a	313.0ab	342.7a	334.1a	326.5a	254.8ab	282.2ab	293.9ab	199.4b	317.7ab
Rootproduction (t∙ha^-1)	33.7a	27.3abc	25.5bc	23.5c	22.6c	33.1ab	26.2abc	10.9e	14.0de	19.3cd	10.4e	9.6e

Components (%)¹ 1 Quantifications based on fresh weight basis. Distinct letters, in the same row, indicate significant differences by Duncan’s test (p < 0.05). GL = Gliricidia + Leucaena; N = Nitrogen; LA = Leucaena + Acacia; LC = Leucaena + Clitoria; GC = Gliricidia + Clitoria; GA = Gliricidia + Acacia; BS = Bare soil.	GL + N^b	LA + N	LC + N	GC + N	GA + N	GL	LA	LC	GC	GA	BS + N	Control
Moisture	58.6ab	62.2ab	60.3ab	57.3b	60.8ab	63.0ab	60.2ab	59.1ab	61.4ab	63.0ab	57.3b	64.0a
Ash	0.54	0.63a	0.66a	0.58a	0.57a	0.57a	0.56a	0.66a	0.63a	0.62a	0.64a	0.59a
Lipids	0.04f	0.07ef	0.07ef	0.16a	0.10bcde	0.09cde	0.10bcde	0.14ab	0.09cde	0.08def	0.12abcd	0.13abc
Protein	0.29ab	0.22cd	0.23bcd	0.32a	0.26abc	0.21cd	0.20cd	0.16d	0.22cd	0.19cd	0.26abc	0.17d
Starch	35.7b	33.9c	34.7bc	38.8a	34.0c	31.5d	33.5c	34.6bc	33.5c	30.1e	38.0a	30.6de
Carbohydrates	40.5a	36.9a	38.7a	41.6a	38.3a	36.1a	38.9a	39.9a	37.7a	36.1a	41.7a	35.1a

Minerals (mg∙kg^-1)¹ 1 Quantifications based on fresh weight basis. Distinct letters, in the same row, indicate significant differences by Duncan’s test (p < 0.05). GL = Gliricidia + Leucaena; N = Nitrogen; LA = Leucaena + Acacia; LC = Leucaena + Clitoria; GC = Gliricidia + Clitoria; GA = Gliricidia + Acacia; BS = Bare soil.	GL + N	LA + N	LC + N	GC + N	GA + N	GL	LA	LC	GC	GA	BS + N	Control
Ca	46.0 c	39.0c	35.0c	52.0c	116.0b	45.0c	50.0c	35.0c	46.0c	51.0c	36.0c	187.0a
Mg	65.0b	43.0b	47.0b	54.0b	68.0b	53.0b	43.0b	55.0b	53.0b	45.0b	63.0 b	93.0a
K	132.0a	75.0c	83.0c	141.0a	112.0b	94.0bc	68.0c	106.0b	124.0ab	94.0c	77.0c	104.0 b
P	170.0a	114.0a	125.0a	162.0a	139.0a	143.0a	120.0a	132.0a	152.0a	122.0a	135.0a	163.0 a
Zn	0.9a	0.8a	0.4a	0.7a	1.0 a	0.8a	0.4a	0.8a	0.7a	0.6a	0.5a	0.9a
Fe	3.5a	2.1bc	1.5c	2.7abc	2.8ab	2.0bc	1.7bc	2.0bc	2.1bc	2.2bc	2.2bc	1.9bc
I	16.0a	11.0b	11.0b	16.0a	13.0ab	12.0ab	11.0b	12.0ab	13.0ab	11.0b	12.0ab	14.0ab

Brasil

Brasil

Food quantity and quality of cassava affected by leguminous residues and inorganic nitrogen application in a soil of low natural fertility of the humid tropics

ABSTRACT

INTRODUCTION

MATERIAL AND METHODS

Experimental site and trial establishment

Soil sampling and analysis

Statistical analysis

RESULTS AND DISCUSSION

CONCLUSION

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History

Carotenoids (mg∙kg^-1)¹	GL + N	LA + N	LC + N	GC + N	GA + N	GL
Lutein	0.04d	0.04d	0.04d	0.05cd	0.04d	0.12a
Zeaxanthin	0.01b	0.01b	0.01b	0.02b	0.01b	0.02b
cis β-cryptoxanthin	0.08b	0.06cd	0.04ef	0.11a	0.05de	0.07bc
cis ζ-carotene	0.05c	0.05c	0.06b	0.06b	0.04d	0.05c
trans ζ-carotene	0.03b	0.03b	0.04a	0.03b	0.04a	0.04a
trans β-carotene	0.44cd	0.43cde	0.32e	1.08a	0.44cd	0.41cde
(9-cis) β-carotene	0.25cd	0.17fgh	0.12hi	0.37b	0.11i	0.19ef
(13-cis) β-carotene	0.18c	0.14cd	0.11d	0.35a	0.13cd	0.14cd
Total	1.6c	1.2e	1.2e	2.1a	1.4d	1.3d
Pro-vitamin A (RAE per 100g)	5.7d	5.2de	3.8f	12.4a	4.9def	5.1def
Carotenoids (mg∙kg^-1)¹	LA	LC	GC	GA	BS + N	Control
Lutein	0.04d	0.08bc	0.04d	0.12a	0.10ab	0.14a
Zeaxanthin	0.01b	0.02b	0.01b	0.02b	0.02b	0.04a
cis β-cryptoxanthin	0.03f	0.10a	0.07bc	0.06cd	0.05de	0.05de
cisζ-carotene	0.06b	0.06b	0.05c	0.05c	0.07a	0.06b
transζ-carotene	0.04a	0.04a	0.03b	0.03b	0.04a	0.04a
trans β-carotene	0.48c	0.76b	0.77b	0.35de	0.43cde	0.46cd
(9-cis) β-carotene	0.28c	0.46a	0.22de	0.14ghi	0.17fgh	0.16fgh
(13-cis) β-carotene	0.17c	0.32a	0.26b	0.11d	0.15cd	0.11d
Total	1.3d	2.0b	1.7c	1.1e	1.3d	1.7c
Pro-vitamin A (RAE per 100g)	6.0d	10.0b	8.7c	4.2ef	5.1def	5.2de