Impact of humic substances and nitrogen fertilising on the fruit quality
               and yield of custard apple

Cunha, Marcelo dos Santos; Cavalcante, Ítalo Herbert Lucena; Mancin, Adriana Cristina; Albano, Francisca Gislene; Marques, Adenaelson Souza

doi:10.4025/actasciagron.v37i2.19511

Abstracts

The custard apple (Annona squamosa L.), also known as the sugar apple, is a fruit species native to Brazil that has been poorly studied, especially in relation to the effect of humic substances on its fruit quality and yield. An experiment was conducted from December 2010 to November 2011 to evaluate the fruit quality and yield of the custard apple as a function of nitrogen fertilising and the use of humic substances. The experimental design consisted of randomised blocks, with treatments distributed in a factorial arrangement (4 x 2), using four nitrogen doses (0, 100, 175 and 250 g of N plant-1) and two humic substance applications (with and without humic substances), with four replications. The fruit yield and fruit characteristics, such as fruit mass, titratable acidity (TA), soluble solids (SS), pulp pH and SS/TA ratio, were recorded. The humic substances and the nitrogen levels significantly affected the soluble solids, titratable acidity and SS/TA ratio, while the pH pulp was only influenced by the humic substances. The humic substances promoted a quantitative increase in the fruit yield of 0.63 ton ha-1. The fruit quality and yield of the custard apple depend on the nitrogen fertiliser and the interaction of the humic substances. Nitrogen fertilising of 100 g per plant, associated with humic substances, could be recommended for use in the production of custard apples.

Annona squamosa L.; fruit yield; humic acids.

A ateira (Annona squamosa L.), também conhecida como pinheira, é uma planta nativa do Brasil pouco estudada, especialmente em relação às substâncias húimicas e seus efeitos na qualidade de frutos e produtividade Nesse sentido, um experimento foi realizado de Dezembro de 2010 a Novembro de 2011 com o objetivo de avaliar a qualidade dos frutos, a produção e a produtividade da ateira em função da adubação nitrogenada e substancias húmicas. Adotou-se delineamento experimental em blocos casualizados com tratamentos distribuídos em esquema fatorial 4 x 2 referentes respectivamente, às doses de N (0, 100, 175 e 250 g de N planta-1), e aplicação de substâncias húmicas (com e sem). Ureia foi usada como fonte de nitrogenio (45% de N) com quatro aplicações mensais de janeiro a abril de 2011. Foram avaliadas ao final do experimento a massa dos frutos, acidez titulável (AT), sólidos solúveis (SS), pH da polpa e ratio SS/AT. Ao final da colheita determinaram-se ainda a produção por planta (kg planta-1) e a produtividade (t ha-1). Produtividade e qualidade de frutos da ateira dependem da interação entre adubação nitrogenada e substâncias húmicas. A adubação nitrogenada com 100 g de N planta-1, consorciada com substâncias húmicas pode ser recomendada para produção de ateira.

Annona squamosa L.; produtividade; ácidos húmicos.

Introduction

The custard apple (Annona squamosa L.), also called the sugar apple, is a small, semi-deciduous tree that is 3-7 m in height and has a broad, open crown or irregularly spreading branches. It is commercially grown, mainly in Brazil, India and Taiwan (PAULL; DUARTE, 2011PAULL, R. E.; DUARTE, O. Tropical fruits. 2nd ed. London: CAB International, 2011.). This plant requires adequate soil moisture during the growing season, and to achieve higher fruit yields, the soil must be fertilised generously, especially with nitrogen, which is the nutrient most required by the custard apple (PLEGUEZUELO et al., 2011PLEGUEZUELO, C. R. R.; ZUAZO, V. H. D.; FERNÁNDEZ, J. L. M.; TARIFA, D. F. Descomposición de hojarasca y reciclado del nitrógeno de frutales tropicales y subtropicales en terrazas de cultivo en la costa de Granada (SE España). Comunicata Scientiae, v. 2, n. 1, p. 42-48, 2011. ; CAVALCANTE et al., 2012CAVALCANTE, Í. H. L.;. CAVALCANTE, L. F; MIRANDA, J. M. S.; MARTINS, A. B. G. Physical and chemical characteristics of tropical and non-conventional fruits. In: VALDEZ, B. (Ed.). Food industrial processes-methods and equipment. 1st ed. Rijeka: InTech, 2012c. p. 1-16. (v. 1)a).

Nitrogen uptake by plant roots is directly affected by soil, plant and environmental factors, which include humic substances (FINZI et al., 2007FINZI, A. C.; NORBYC, R. J.; CALFAPIETRAD, C.; GALLET-BUDYNEKA, A.; GIELENE, B.; HOLMES, F. W. E.; HOOSBEEKG, M. R.; IVERSENH, C. M.; JACKSONI, R. B.; KUBISKE, J. M. E.; LEDFORDC, J.; LIBERLOOE, M.; ORENI, R.; POLLEK, A.; PRITCHARDL, S.; ZAKF, D. R.; SCHLESINGERB, W. H.; CEULEMANSE, R. Increases in nitrogen uptake rather than nitrogen-use efficiency support higher rates of temperate forest productivity under elevated CO2. Proceedings of the National Academy of Sciences of the United States of America, v. 104, n. 35, p. 14014-14019, 2007.). Humic substances act on the mechanisms involved in cell respiration, photosynthesis, protein synthesis, water and nutrient uptake, enzyme activities (NARDI et al., 2000NARDI, S.; PIZZEGHELLO, D.; GESSA, C.; FERRARESE, L.; TRAINOTTI, L.; CASADORO, G. A. Low molecular weight humic fraction on nitrate uptake and protein synthesis in maize seedlings. Soil Biology and Biochemistry, v. 32, n. 3, p. 415-419, 2000.; TAHIR et al., 2011TAHIR, M. M.; KHURSHID, M.; KHAN, M. Z.; ABBASI, M. K.; KAZMI, M. H. Lignite-derived humic acid effect on growth of wheat plants in different Soils. Pedosphere, v. 21, n. 1, p. 124-131, 2011.) and hormones (TREVISAN et al., 2010TREVISAN, S.;. PIZZEGHELLO, D; RUPERTI, B.; FRANCIOSO, O.; SASSI, A.; PALME K.; QUAGGIOTTI, S. Humic substances induce ateral root formation and expression of the early auxin-responsive IAA 19 gene and DR5 synthetic element in Arabidopsis. Plant Biology, v. 12, n. 4, p. 604-614, 2010.), thus stimulating plant growth. Humic substances, when applied directly onto the soil or substrate, have been used for plant production because these substances improve soil fertility and nutrient availability, according to Eyheraguibel et al. (2008EYHERAGUIBEL, B.; SILVESTRE, J.; MORARD, P. Effects of humic substances derived from organic waste enhancement on the growth and mineral nutrition of maize. Bioresourse Technolology, v. 99, n. 10, p. 4206-4212, 2008. ).

Studies on the use of humic substances on fruit species are rarely reported in the literature; however, some investigations have been conducted with papaya (CAVALCANTE et al., 2011CAVALCANTE, Í. H. L.;. SILVA, R. R. S; ALBANO, F. G.; LIMA, F. N.; MARQUES, A. S. Foliar spray of humic substances on seedling production of papaya. Journal of Agronomy, v. 10, n. 4, p. 118-122, 2011b.b), grape (FERRARA; BRUNETTI, 2008FERRARA, G.; BRUNETTI, G. Influence of foliar applications of humic acids on yield and fruit quality of Table grape cv. Itália. Journal International des Sciences de la Vigne et du Vin, v. 42, n. 2, p. 79-88, 2008.) and watermelon (SALMAN et al., 2005SALMAN, S. R.; ABOU-HUSSEIN, S. D.; ABDEL-MAWGOUD, A. M. R.; EL-NEMR, M. A. Fruit yield and quality of watermelon as affected by hybrids and humic acid application. Journal of Applied Sciences Research, v. 1, n. 1, p. 51-58, 2005. ), with promising results. In addition, studies on fertilising yellow passion fruit with products containing humic substances developed under field conditions can be found in the scientific literature, including studies by Cavalcante et al. (2008CAVALCANTE, L. F.;. CAVALCANTE, Í. H. L; SANTOS, G. D. Micronutrient and sodium foliar contents of yellow passion fruit plants as a function of biofertilizers., Fruits v. 63, n. 1, p. 27-36, 2008.) and Cavalcante et al. (2012CAVALCANTE, Í. H. L.;. CAVALCANTE, L. F; MIRANDA, J. M. S.; MARTINS, A. B. G. Physical and chemical characteristics of tropical and non-conventional fruits. In: VALDEZ, B. (Ed.). Food industrial processes-methods and equipment. 1st ed. Rijeka: InTech, 2012c. p. 1-16. (v. 1)b). However, the effect of humic substances on custard apple production, especially in combination with nitrogen fertilising, has been poorly quantified.

Hence, the present study aimed to evaluate the fruit quality and yield of the custard apple as a function of nitrogen fertilising and the use of humic substances in Brazil.

Material and methods

Plant material and growth conditions

Custard apple (Annona squamosa L.) plants that were five years old and propagated by seeds were used in this study.

The study was conducted from December 2010 to May 2011 (first trial) and from June 2011 to November 2011 (second trial) at "Campus Profa. Cinobelina Elvas," Federal University of Piaui, Piaui State, Brazil (Northeastern Brazil).

The physical and chemical characteristics of the soil developed for the experiment are shown in Table 1. The climatic data regarding air temperature and air humidity (thermo-hygrometer Instrutemp⁽, Brazil) collected during the experiments are shown in Figure 1.

The plants, spaced with 4 m between the rows and 3 m between the plants, were daily drip-irrigated with one self-regulating emitter at every 0.5 m, for a flow of 2.8 L h^-1. Pruning was performed following the instructions of Paull and Duarte (2011PAULL, R. E.; DUARTE, O. Tropical fruits. 2nd ed. London: CAB International, 2011.).

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Table 1:
Chemical and physical characteristics of the soil (0-20 cm soil depth) where the experiment was carried out.

The plot was limed with 1,500 kg ha^-1 or 1.80 kg plant^-1 60 days before the beginning of the experiment, and all of the plants were fertilised with 120 g of K₂O (potassium chloride, 60% K₂O) at 30, 60 and 90 days after pruning and with 120 g of P2O5 (triple superphosphate, 42% P₂O₅) at 30 days after pruning, according to the instructions by Anonymous (1993).

The nitrogen source used was urea (45% N) and was applied monthly (four fertilisings), according to the instructions of Anonymous (1993). The humic substances used in the experiment were extracted from leonardite, and the source adopted was Humitec⁽, whose complete composition included humic extract (16.5%), organic carbon (11.2%), humic acids (13.2%) and fulvic acids (3.3%). The humic substances were applied following the recommendations of the producer, i.e., 30 mL diluted in 3 L of water applied every 60 days after pruning, totalling two applications for each experiment.

Treatments and experimental design

The experimental design consisted of randomised blocks with treatments distributed in a factorial arrangement (4 x 2) of four nitrogen doses (0, 100, 175 and 250 g of N plant^-1) and two humic substances application (with and without humic substances), with four replications.

Variables Recorded and Statistical Analysis

During the fruit harvest time, i.e., April-May 2011 and October-November 2011, 10 fruits per parcel were manually harvested when their carpels were separated and the intercarpel tissue was yellowish green.

Figure 1:
Average temperature and air humidity during the execution of the experiments. (A and B - first trial; C and D - second trial.

The fruits were placed in paper bags and taken to the Food Laboratory at the Federal University of Piaui, Bom Jesus, Brazil. This parameter for fruit selection was recommended by Kavati and Piza Junior (1997KAVATI, R.; PIZA JR., C. T. Formação e manejo do pomar de fruta-do-conde, atemóia e cherimóia. In:. SÃO JOSÉ, A. R; SOUZA, I. V. B.; MORAIS, O. M.;. REBOUÇAS, T. N. H (Ed.). Anonáceas: produção e mercado (pinha, graviola, atemóia e cherimóia). Vitória da Conquista: UESB-DFZ, 1997. p. 75-83.) for commercial farms

The fruit analyses of the custard apple fruits included the usual parameters: i) the fruit mass was measured using a Sartorious^(r) (Göttingen, Germany) brand precision balance (0.01 g precision) and expressed in g; ii) for the titratable acidity (TA), 20 g of macerated fruit pulp was taken from yellow passion fruits and brought to a final volume of 100 mL by adding distilled water. A 20-mL sample was taken from the mixture, and three to four drops of phthalein were used as an indicator. This suspension was titrated with 0.1 N sodium hydroxide (NaOH). The results were expressed as a percentage; iii) the soluble solids (SS), expressed as °Brix, were measured using an Abbe^(r) refractometer (Bausch and Lomb, Rochester, NY, USA); iv) the pulp pH was measured using a Marconi^(r)pH meter; v) after chemical analyses, the relation between the soluble solids and the titratable acidity (SS/TA ratio) was calculated; and vi) the fruit yield were measured as ton ha^-1.

Statistical analyses included analysis of variance (ANOVA), a mean separation of humic substances using the Tukey test and regression analysis of the nitrogen doses using the combined data of two consecutive trials. All calculations were performed using the Sigmaplot software, and the terms were considered significant at p < 0.01.

Results and discussion

As observed in Table 2, the humic nitrogen levels significantly affected the soluble solids (SS), titratable acidity (TA) and SS/TA ratio, while the pH pulp was only influenced by the humic substances. In addition, significant interactions between the N levels and humic substances were registered for all the fruit variables recorded in the study.

Independent of the humic substance use (Figure 2A and B), the pulp pH of the custard apple fruits

increased with increasing nitrogen levels until it reached 100 g per plant, and this increase was immediately followed by decay. Cavalcante et al. (2012CAVALCANTE, Í. H. L.;. CAVALCANTE, L. F; MIRANDA, J. M. S.; MARTINS, A. B. G. Physical and chemical characteristics of tropical and non-conventional fruits. In: VALDEZ, B. (Ed.). Food industrial processes-methods and equipment. 1st ed. Rijeka: InTech, 2012c. p. 1-16. (v. 1)c) reported that fruit pH is a characteristic used to evaluate the acid components of fruits and their shelf life, reporting that less acid fruits are more often recommended for fresh consumption, while acid fruits are more appropriate for the food industry. It is important to note that the use of humic substances reduced the pulp pH by nearly 1.94%. This is a relevant fact for this fruit species because most custard apple fruits are consumed as fresh fruit.

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Table 2:
Fruit characteristics [mass, pulp pH, soluble solids (SS), tritatable acidity (TA), "SS/TA ratio" and yield] of custard apple fruits as a function of humic substances and nitrogen. fertilizing.

The effects of the nitrogen fertilising levels on the soluble solids of the custard apple fruits were significantly impacted by the use of humic substances. In the plants that received the humic substances, the soluble solids of the fruits increased by approximately 2.8% after using 0 to 100 g of N per plant and decreased by 6.25% after using 100 to 250 g of N per plant (Figure 2C). Conversely, the plants that were not treated with humic substances presented an exponential decay with the increasing nitrogen levels (Figure 2D). The reduction of fruit soluble solids as a function of an increasing nitrogen level was previously reported by Silva et al. (2002SILVA, J.; SILVA, E. S.; SILVA, P. S. L. Determinação da qualidade e do teor de sólidos solúveis nas diferentes partes do fruto da pinheira (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 24, n. 2, p. 562-564, 2002.), and this reduction could be explained by the positive and direct effect of humic substances on the root absorption of ammonium nitrate (KEELING et al., 2003KEELING, A. A.; MCCALLUM, K. R.; BECKWITH, C. P. Manure Green waste compost enhances growth and nitrogen uptake in wheat (Triticum aestivum L.) and oilseed (Brassica napus L.) through the action of water-extractable factors. Bioresourse Technology, v. 90, n. 2, p. 127-132, 2003.).

Independent of the treatment, the averages presented in Figures 2C and D are much higher than the 25.5-27.5 ºBrix range reported by Pereira et al. (2003PEREIRA, M. C. T.; NIETSCHE, S.; SANTOS, F. S.; XAVIER, A. A.; CUNHA, L. M. V.; NUNES, F. C.; SANTOS, F. A. Efeito de horários de polinização artificial no pegamento e qualidade de frutos de pinha (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 25, n. 2, p. 203-205, 2003.), the 19.7-21.1 ºBrix range registered by Silva et al. (2007) and the 15.3-22.8 ºBrix range found by Cavalcante et al. (2011CAVALCANTE, Í. H. L.;. SILVA, R. R. S; ALBANO, F. G.; LIMA, F. N.; MARQUES, A. S. Foliar spray of humic substances on seedling production of papaya. Journal of Agronomy, v. 10, n. 4, p. 118-122, 2011b.a) in a study of fruit quality as a parameter for the selection of custard apple genotypes in Brazil.

As observed in Figure 2E, the increase in nitrogen levels promoted a significant decrease in the fruit titratable acidity of 19.61% from the minimum (0 g of N per plant) to the maximum (250 g of N per plant) nitrogen levels. When comparing the titratable acidity results of the present study with those registered in the scientific literature, it is possible to infer that the 0.59% average recorded here is higher than the 0.22-0.25% range reported by Dias et al. (2003DIAS, N. O.; MATUSOMOTO, S. N.; REBOUÇAS, T. N. H.; VIANA, A. E. S.; SÃO JOSÉ, A. R.; SOUZA, I. B. V. Influencia da poda de produção em ramos de diferentes diâmetros de desenvolvimento vegetativo e reprodutivo da pinheira (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 25, n. 1, p. 100-103, 2003.), who examined the effect of pruning on fruit quality, and higher than the 0.15% recorded by Bolívar-Fernández et al. (2009BOLÍVAR-FERNANDEZ, N.; SAUCEDO-VELOZ, C.; SOLIS-PEREIRA, S.; SAURI-DUCH, E. Ripening of sugar apple fruits (Annona squamosa L.) developed in Yucatan, Mexico. Agrociencia, v. 43, n. 2, p. 133-141, 2009.), who compared different custard apple genotypes. Accordingly, Cavalcante et al. (2012cCAVALCANTE, Í. H. L.;. CAVALCANTE, L. F; MIRANDA, J. M. S.; MARTINS, A. B. G. Physical and chemical characteristics of tropical and non-conventional fruits. In: VALDEZ, B. (Ed.). Food industrial processes-methods and equipment. 1st ed. Rijeka: InTech, 2012c. p. 1-16. (v. 1)) argued that high titratable acidity is important for fruit processing because this high acidity reduces the necessity of adding artificial acid components, although this is not a limiting factor in genotype selection when other fruit quality parameters are satisfactory. Low titratable acidity is relevant to consumption as a fresh fruit.

Without the use of humic substances, the SS/TA ratio followed the same tendency of the soluble solids (Figure 2F), i.e., a higher average value registered after using less than 100 g of N per plant, while the use of humic substances produced a sequential increase of this variable with an increase in nitrogen levels (Figure 2G), showing that the soluble solids were more influential on the SS/TA ratio and titritable acidity. Additionally, all of the averages are lower than those reported by Silva et al. (2007SILVA, P. S. L.; ANTONIO, R. F.; MARIGUELE, K. H.; SILVA, K. M. B.; LIMA, L. K.; SILVA, J. S. V. Estimates of genetic parameters for fruit yield and quality in custard apple progenies., Revista Brasileira de Fruticultura v. 29, n. 3, p. 550-558, 2007.) and Cavalcante et al. (2011CAVALCANTE, Í. H. L.;. SILVA, R. R. S; ALBANO, F. G.; LIMA, F. N.; MARQUES, A. S. Foliar spray of humic substances on seedling production of papaya. Journal of Agronomy, v. 10, n. 4, p. 118-122, 2011b.a).

Regarded individually, the soluble solids and titratable acidity characteristics can represent a false indication of fruit flavour, while the soluble solids/titratable acidity ratio is considered a practical form, mainly for consumption as fresh fruit (CAVALCANTE et al., 2007CAVALCANTE, Í. H. L.; BECKMANN, M. Z.; MARTINS, A. B. M.; CAMPOS, M. C. C. Preliminary selection of acerola genotypes in Brazil. Fruits, v. 62, n. 1, p. 1-8, 2007.).

The average mass of the individual fruits was not affected by either the nitrogen levels or the humic substances (Table 2). The fruits produced in this study are heavier, on average, than those recorded by Cavalcante et al. (2011CAVALCANTE, Í. H. L.;. SILVA, R. R. S; ALBANO, F. G.; LIMA, F. N.; MARQUES, A. S. Foliar spray of humic substances on seedling production of papaya. Journal of Agronomy, v. 10, n. 4, p. 118-122, 2011b.a) but lighter than the 274 g obtained by Costa et al. (2002COSTA, L. S.; CARVALHO, A. J. C. C.; PESSANHA, P. G. O. P.; MONNERAT, P. H.; MARINHO, C. S. Produtividade da cultura da pinha (Annona squamosa L.) em função de níveis de adubação nitrogenada e formas de aplicação de boro. Revista Brasileira de Fruticultura, v. 24, n. 2, p. 543-546, 2002.) and the 220 g recorded by Girwani et al. (2011GIRWANI, A.; MADHAVI, A.; KUMAR, T. S.; REDDY, G. S. Evaluation of custard apple hybrids for fruit yield and quality attributing characters. Acta Horticulturae, n. 890, p. 251-254, 2011.) for the custard apple hybrid-4 ('1/6 British Guinea' x 'Atemoya') in India. In addition, the higher average value of the present study is comparable to the maximum one registered by Kumar et al. (2011KUMAR, S. T.; GIRWANI, G.; REDDY, S.; BHAGWAN, A. Studies on nutrient management in custard apple "banalagar"., Acta Horticulturae n. 890, p. 381-385, 2011.) in India.

Figure 2:
Pulp pH (A e B), soluble solids (C e D), titratable acidity (E) and SS/TA "Ratio" SS/AT (F e G) of custard apple fruits as a function nitrogen levels and humic substances. [A, C and F: without humic substances; B, D and G: with humic substances].

The fruit yields of the custard apple were similar for the plants with and without humic substances, as observed in a quadratic adjustment with a minimum fit of 0.80 with humic substances and 0.85 without humic substances and at a peak at 100 g of N per plant (Figures 3A and B). Accordingly, from 0 to 100 g of N per plant, an increase in fruit yield of 10.00 and 5.89%, respectively, was registered for the plants without and with humic substances. This increase could be explained by the good soil fertility conditions before the experiment (Table 1) and may be associated with the beneficial effects of humic substances on the soil and plant, as previously described by Tahir et al. (2011TAHIR, M. M.; KHURSHID, M.; KHAN, M. Z.; ABBASI, M. K.; KAZMI, M. H. Lignite-derived humic acid effect on growth of wheat plants in different Soils. Pedosphere, v. 21, n. 1, p. 124-131, 2011.). In addition, among all nutrients, nitrogen presents fundamental importance because it forms part of amino acids, proteins and nucleic acids and because it directly or indirectly acts on many biochemical plant processes (SHI et al., 2012SHI, Z.; LI, D.; JING, Q.; CAI, J.; JIANG, D.; CAO, W.; DAI, T. Effects of nitrogen applications on soil nitrogen balance and nitrogen utilization of winter wheat in a rice-wheat rotation. Field Crops Research, v. 127, p. 241-247, 2012.). However, its association with humic substances and its physiological consequences for custard apple plants has been poorly studied.

Figure 3:
Fruit yield of custard apple fruits as a function nitrogen levels and humic substances. [A: without humic substances; B: with humic substances.

Despite the lack of significant statistical effects (Table 2), the plants that received humic substances presented a quantitative difference in fruit yield of 0.63 ton ha^-1 in relation to those that did not receive this product. That yield is considered a high income for fruit growers in Brazil.

Independent of the humic substance use, the average yield values quoted in the present study are higher than the average values quoted in the scientific literature, such as 3.2 ton ha^-1 (KAVATI; PIZA JR., 1997KAVATI, R.; PIZA JR., C. T. Formação e manejo do pomar de fruta-do-conde, atemóia e cherimóia. In:. SÃO JOSÉ, A. R; SOUZA, I. V. B.; MORAIS, O. M.;. REBOUÇAS, T. N. H (Ed.). Anonáceas: produção e mercado (pinha, graviola, atemóia e cherimóia). Vitória da Conquista: UESB-DFZ, 1997. p. 75-83.) and 6.10 ton ha^-1 (COSTA et al., 2002COSTA, L. S.; CARVALHO, A. J. C. C.; PESSANHA, P. G. O. P.; MONNERAT, P. H.; MARINHO, C. S. Produtividade da cultura da pinha (Annona squamosa L.) em função de níveis de adubação nitrogenada e formas de aplicação de boro. Revista Brasileira de Fruticultura, v. 24, n. 2, p. 543-546, 2002.) in Brazil and 5.0 ton ha^-1 (PATEL et al., 2010PATEL, N. M.; PATEL, D. K.; VERMA, L. R.; PATEL, M. M. Effect of cultural and chemical treatments on fruit set and fruit yield of custard apple (Annona sqamosa Linn.) cv. Sindhan. Asian Journal of Horticulture, v. 5, n. 2, p. 498-502, 2010. ) in India.

In general, the average values registered in the study are higher than those verified by Kumar et al. (2011KUMAR, S. T.; GIRWANI, G.; REDDY, S.; BHAGWAN, A. Studies on nutrient management in custard apple "banalagar"., Acta Horticulturae n. 890, p. 381-385, 2011.), who recommend a substantially higher amount of fertiliser. The previous authors indicated that for high custard apple yields, it is necessary to use 400 g of N per plant, a level not evaluated in the present study.

Conclusion

Thus, the results of this study indicate that i) the fruit quality and yield of the custard apple depend on the interaction of nitrogen fertilising and humic substances; and ii) under the soil, climate and plant conditions of this study, 100 g of N per plant of cover fertilising, associated with humic substances, could be recommended for the production of custard apples.

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CAVALCANTE, Í. H. L.;. CAVALCANTE, L. F; MIRANDA, J. M. S.; MARTINS, A. B. G. Physical and chemical characteristics of tropical and non-conventional fruits. In: VALDEZ, B. (Ed.). Food industrial processes-methods and equipment. 1st ed. Rijeka: InTech, 2012c. p. 1-16. (v. 1)
CAVALCANTE, L. F.;. CAVALCANTE, Í. H. L; SANTOS, G. D. Micronutrient and sodium foliar contents of yellow passion fruit plants as a function of biofertilizers., Fruits v. 63, n. 1, p. 27-36, 2008.
COSTA, L. S.; CARVALHO, A. J. C. C.; PESSANHA, P. G. O. P.; MONNERAT, P. H.; MARINHO, C. S. Produtividade da cultura da pinha (Annona squamosa L.) em função de níveis de adubação nitrogenada e formas de aplicação de boro. Revista Brasileira de Fruticultura, v. 24, n. 2, p. 543-546, 2002.
DIAS, N. O.; MATUSOMOTO, S. N.; REBOUÇAS, T. N. H.; VIANA, A. E. S.; SÃO JOSÉ, A. R.; SOUZA, I. B. V. Influencia da poda de produção em ramos de diferentes diâmetros de desenvolvimento vegetativo e reprodutivo da pinheira (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 25, n. 1, p. 100-103, 2003.
EYHERAGUIBEL, B.; SILVESTRE, J.; MORARD, P. Effects of humic substances derived from organic waste enhancement on the growth and mineral nutrition of maize. Bioresourse Technolology, v. 99, n. 10, p. 4206-4212, 2008.
FERRARA, G.; BRUNETTI, G. Influence of foliar applications of humic acids on yield and fruit quality of Table grape cv. Itália. Journal International des Sciences de la Vigne et du Vin, v. 42, n. 2, p. 79-88, 2008.
FINZI, A. C.; NORBYC, R. J.; CALFAPIETRAD, C.; GALLET-BUDYNEKA, A.; GIELENE, B.; HOLMES, F. W. E.; HOOSBEEKG, M. R.; IVERSENH, C. M.; JACKSONI, R. B.; KUBISKE, J. M. E.; LEDFORDC, J.; LIBERLOOE, M.; ORENI, R.; POLLEK, A.; PRITCHARDL, S.; ZAKF, D. R.; SCHLESINGERB, W. H.; CEULEMANSE, R. Increases in nitrogen uptake rather than nitrogen-use efficiency support higher rates of temperate forest productivity under elevated CO2. Proceedings of the National Academy of Sciences of the United States of America, v. 104, n. 35, p. 14014-14019, 2007.
GIRWANI, A.; MADHAVI, A.; KUMAR, T. S.; REDDY, G. S. Evaluation of custard apple hybrids for fruit yield and quality attributing characters. Acta Horticulturae, n. 890, p. 251-254, 2011.
KAVATI, R.; PIZA JR., C. T. Formação e manejo do pomar de fruta-do-conde, atemóia e cherimóia. In:. SÃO JOSÉ, A. R; SOUZA, I. V. B.; MORAIS, O. M.;. REBOUÇAS, T. N. H (Ed.). Anonáceas: produção e mercado (pinha, graviola, atemóia e cherimóia). Vitória da Conquista: UESB-DFZ, 1997. p. 75-83.
KEELING, A. A.; MCCALLUM, K. R.; BECKWITH, C. P. Manure Green waste compost enhances growth and nitrogen uptake in wheat (Triticum aestivum L.) and oilseed (Brassica napus L.) through the action of water-extractable factors. Bioresourse Technology, v. 90, n. 2, p. 127-132, 2003.
KUMAR, S. T.; GIRWANI, G.; REDDY, S.; BHAGWAN, A. Studies on nutrient management in custard apple "banalagar"., Acta Horticulturae n. 890, p. 381-385, 2011.
NARDI, S.; PIZZEGHELLO, D.; GESSA, C.; FERRARESE, L.; TRAINOTTI, L.; CASADORO, G. A. Low molecular weight humic fraction on nitrate uptake and protein synthesis in maize seedlings. Soil Biology and Biochemistry, v. 32, n. 3, p. 415-419, 2000.
PATEL, N. M.; PATEL, D. K.; VERMA, L. R.; PATEL, M. M. Effect of cultural and chemical treatments on fruit set and fruit yield of custard apple (Annona sqamosa Linn.) cv. Sindhan. Asian Journal of Horticulture, v. 5, n. 2, p. 498-502, 2010.
PAULL, R. E.; DUARTE, O. Tropical fruits. 2nd ed. London: CAB International, 2011.
PEREIRA, M. C. T.; NIETSCHE, S.; SANTOS, F. S.; XAVIER, A. A.; CUNHA, L. M. V.; NUNES, F. C.; SANTOS, F. A. Efeito de horários de polinização artificial no pegamento e qualidade de frutos de pinha (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 25, n. 2, p. 203-205, 2003.
PLEGUEZUELO, C. R. R.; ZUAZO, V. H. D.; FERNÁNDEZ, J. L. M.; TARIFA, D. F. Descomposición de hojarasca y reciclado del nitrógeno de frutales tropicales y subtropicales en terrazas de cultivo en la costa de Granada (SE España). Comunicata Scientiae, v. 2, n. 1, p. 42-48, 2011.
SALMAN, S. R.; ABOU-HUSSEIN, S. D.; ABDEL-MAWGOUD, A. M. R.; EL-NEMR, M. A. Fruit yield and quality of watermelon as affected by hybrids and humic acid application. Journal of Applied Sciences Research, v. 1, n. 1, p. 51-58, 2005.
SHI, Z.; LI, D.; JING, Q.; CAI, J.; JIANG, D.; CAO, W.; DAI, T. Effects of nitrogen applications on soil nitrogen balance and nitrogen utilization of winter wheat in a rice-wheat rotation. Field Crops Research, v. 127, p. 241-247, 2012.
SILVA, J.; SILVA, E. S.; SILVA, P. S. L. Determinação da qualidade e do teor de sólidos solúveis nas diferentes partes do fruto da pinheira (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 24, n. 2, p. 562-564, 2002.
SILVA, P. S. L.; ANTONIO, R. F.; MARIGUELE, K. H.; SILVA, K. M. B.; LIMA, L. K.; SILVA, J. S. V. Estimates of genetic parameters for fruit yield and quality in custard apple progenies., Revista Brasileira de Fruticultura v. 29, n. 3, p. 550-558, 2007.
TAHIR, M. M.; KHURSHID, M.; KHAN, M. Z.; ABBASI, M. K.; KAZMI, M. H. Lignite-derived humic acid effect on growth of wheat plants in different Soils. Pedosphere, v. 21, n. 1, p. 124-131, 2011.
TREVISAN, S.;. PIZZEGHELLO, D; RUPERTI, B.; FRANCIOSO, O.; SASSI, A.; PALME K.; QUAGGIOTTI, S. Humic substances induce ateral root formation and expression of the early auxin-responsive IAA 19 gene and DR5 synthetic element in Arabidopsis. Plant Biology, v. 12, n. 4, p. 604-614, 2010.

Publication Dates

Publication in this collection
June 2015

History

Received
21 Dec 2012
Accepted
06 Apr 2013

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

[1] ANONYMOUS. Recomendação de adubação e calagem para o estado do Ceará. Fortaleza: Banco do Nordeste do Brasil, 1993.

[2] BOLÍVAR-FERNANDEZ, N.; SAUCEDO-VELOZ, C.; SOLIS-PEREIRA, S.; SAURI-DUCH, E. Ripening of sugar apple fruits (Annona squamosa L.) developed in Yucatan, Mexico. Agrociencia, v. 43, n. 2, p. 133-141, 2009.

[3] CAVALCANTE, Í. H. L.; BECKMANN, M. Z.; MARTINS, A. B. M.; CAMPOS, M. C. C. Preliminary selection of acerola genotypes in Brazil. Fruits, v. 62, n. 1, p. 1-8, 2007.

[4] CAVALCANTE, Í. H. L.; MOURA, M. C. S.; ROCHA, L. F.; SILVA JUNIOR, G. B.; MARTINS, L. V.; SILVA, R. R. S. Seleção preliminar de pinheira em Bom Jesus, PI. Revista de Ciências Agrárias, v. 34, n. 3, p. 171-179, 2011a.

[5] CAVALCANTE, Í. H. L.;. SILVA, R. R. S; ALBANO, F. G.; LIMA, F. N.; MARQUES, A. S. Foliar spray of humic substances on seedling production of papaya. Journal of Agronomy, v. 10, n. 4, p. 118-122, 2011b.

[6] CAVALCANTE, L. F.; PEREIRA, W. E.; CURVÊLO, C. R. S.; NASCIMENTO, J. A. M.;. CAVALCANTE, Í. H. L Estado nutricional de pinheira sob adubação orgânica do solo. Ciência Agronômica, v. 43, n. 3, p. 579-588, 2012a.

[7] CAVALCANTE, L. F.;. CAVALCANTE, Í. H. L; RODOLFO JR., F.; BECKMANN-CAVALCANTE, M. Z.; SANTOS, G. P. Leaf-Macronutrient status and fruit yield of biofertilized yellow passion fruit plants. Journal of Plant Nutrition, v. 35, n. 2, p. 176-191, 2012b.

[8] CAVALCANTE, Í. H. L.;. CAVALCANTE, L. F; MIRANDA, J. M. S.; MARTINS, A. B. G. Physical and chemical characteristics of tropical and non-conventional fruits. In: VALDEZ, B. (Ed.). Food industrial processes-methods and equipment. 1st ed. Rijeka: InTech, 2012c. p. 1-16. (v. 1)

[9] CAVALCANTE, L. F.;. CAVALCANTE, Í. H. L; SANTOS, G. D. Micronutrient and sodium foliar contents of yellow passion fruit plants as a function of biofertilizers., Fruits v. 63, n. 1, p. 27-36, 2008.

[10] COSTA, L. S.; CARVALHO, A. J. C. C.; PESSANHA, P. G. O. P.; MONNERAT, P. H.; MARINHO, C. S. Produtividade da cultura da pinha (Annona squamosa L.) em função de níveis de adubação nitrogenada e formas de aplicação de boro. Revista Brasileira de Fruticultura, v. 24, n. 2, p. 543-546, 2002.

[11] DIAS, N. O.; MATUSOMOTO, S. N.; REBOUÇAS, T. N. H.; VIANA, A. E. S.; SÃO JOSÉ, A. R.; SOUZA, I. B. V. Influencia da poda de produção em ramos de diferentes diâmetros de desenvolvimento vegetativo e reprodutivo da pinheira (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 25, n. 1, p. 100-103, 2003.

[12] EYHERAGUIBEL, B.; SILVESTRE, J.; MORARD, P. Effects of humic substances derived from organic waste enhancement on the growth and mineral nutrition of maize. Bioresourse Technolology, v. 99, n. 10, p. 4206-4212, 2008.

[13] FERRARA, G.; BRUNETTI, G. Influence of foliar applications of humic acids on yield and fruit quality of Table grape cv. Itália. Journal International des Sciences de la Vigne et du Vin, v. 42, n. 2, p. 79-88, 2008.

[14] FINZI, A. C.; NORBYC, R. J.; CALFAPIETRAD, C.; GALLET-BUDYNEKA, A.; GIELENE, B.; HOLMES, F. W. E.; HOOSBEEKG, M. R.; IVERSENH, C. M.; JACKSONI, R. B.; KUBISKE, J. M. E.; LEDFORDC, J.; LIBERLOOE, M.; ORENI, R.; POLLEK, A.; PRITCHARDL, S.; ZAKF, D. R.; SCHLESINGERB, W. H.; CEULEMANSE, R. Increases in nitrogen uptake rather than nitrogen-use efficiency support higher rates of temperate forest productivity under elevated CO2. Proceedings of the National Academy of Sciences of the United States of America, v. 104, n. 35, p. 14014-14019, 2007.

[15] GIRWANI, A.; MADHAVI, A.; KUMAR, T. S.; REDDY, G. S. Evaluation of custard apple hybrids for fruit yield and quality attributing characters. Acta Horticulturae, n. 890, p. 251-254, 2011.

[16] KAVATI, R.; PIZA JR., C. T. Formação e manejo do pomar de fruta-do-conde, atemóia e cherimóia. In:. SÃO JOSÉ, A. R; SOUZA, I. V. B.; MORAIS, O. M.;. REBOUÇAS, T. N. H (Ed.). Anonáceas: produção e mercado (pinha, graviola, atemóia e cherimóia). Vitória da Conquista: UESB-DFZ, 1997. p. 75-83.

[17] KEELING, A. A.; MCCALLUM, K. R.; BECKWITH, C. P. Manure Green waste compost enhances growth and nitrogen uptake in wheat (Triticum aestivum L.) and oilseed (Brassica napus L.) through the action of water-extractable factors. Bioresourse Technology, v. 90, n. 2, p. 127-132, 2003.

[18] KUMAR, S. T.; GIRWANI, G.; REDDY, S.; BHAGWAN, A. Studies on nutrient management in custard apple "banalagar"., Acta Horticulturae n. 890, p. 381-385, 2011.

[19] NARDI, S.; PIZZEGHELLO, D.; GESSA, C.; FERRARESE, L.; TRAINOTTI, L.; CASADORO, G. A. Low molecular weight humic fraction on nitrate uptake and protein synthesis in maize seedlings. Soil Biology and Biochemistry, v. 32, n. 3, p. 415-419, 2000.

[20] PATEL, N. M.; PATEL, D. K.; VERMA, L. R.; PATEL, M. M. Effect of cultural and chemical treatments on fruit set and fruit yield of custard apple (Annona sqamosa Linn.) cv. Sindhan. Asian Journal of Horticulture, v. 5, n. 2, p. 498-502, 2010.

[21] PAULL, R. E.; DUARTE, O. Tropical fruits. 2nd ed. London: CAB International, 2011.

[22] PEREIRA, M. C. T.; NIETSCHE, S.; SANTOS, F. S.; XAVIER, A. A.; CUNHA, L. M. V.; NUNES, F. C.; SANTOS, F. A. Efeito de horários de polinização artificial no pegamento e qualidade de frutos de pinha (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 25, n. 2, p. 203-205, 2003.

[23] PLEGUEZUELO, C. R. R.; ZUAZO, V. H. D.; FERNÁNDEZ, J. L. M.; TARIFA, D. F. Descomposición de hojarasca y reciclado del nitrógeno de frutales tropicales y subtropicales en terrazas de cultivo en la costa de Granada (SE España). Comunicata Scientiae, v. 2, n. 1, p. 42-48, 2011.

[24] SALMAN, S. R.; ABOU-HUSSEIN, S. D.; ABDEL-MAWGOUD, A. M. R.; EL-NEMR, M. A. Fruit yield and quality of watermelon as affected by hybrids and humic acid application. Journal of Applied Sciences Research, v. 1, n. 1, p. 51-58, 2005.

[25] SHI, Z.; LI, D.; JING, Q.; CAI, J.; JIANG, D.; CAO, W.; DAI, T. Effects of nitrogen applications on soil nitrogen balance and nitrogen utilization of winter wheat in a rice-wheat rotation. Field Crops Research, v. 127, p. 241-247, 2012.

[26] SILVA, J.; SILVA, E. S.; SILVA, P. S. L. Determinação da qualidade e do teor de sólidos solúveis nas diferentes partes do fruto da pinheira (Annona squamosa L.)., Revista Brasileira de Fruticultura v. 24, n. 2, p. 562-564, 2002.

[27] SILVA, P. S. L.; ANTONIO, R. F.; MARIGUELE, K. H.; SILVA, K. M. B.; LIMA, L. K.; SILVA, J. S. V. Estimates of genetic parameters for fruit yield and quality in custard apple progenies., Revista Brasileira de Fruticultura v. 29, n. 3, p. 550-558, 2007.

[28] TAHIR, M. M.; KHURSHID, M.; KHAN, M. Z.; ABBASI, M. K.; KAZMI, M. H. Lignite-derived humic acid effect on growth of wheat plants in different Soils. Pedosphere, v. 21, n. 1, p. 124-131, 2011.

[29] TREVISAN, S.;. PIZZEGHELLO, D; RUPERTI, B.; FRANCIOSO, O.; SASSI, A.; PALME K.; QUAGGIOTTI, S. Humic substances induce ateral root formation and expression of the early auxin-responsive IAA 19 gene and DR5 synthetic element in Arabidopsis. Plant Biology, v. 12, n. 4, p. 604-614, 2010.

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