Microsoft Word - 5-Agra_29714.doc 873 Original Article Biosci. J., Uberlândia, v. 32, n. 4, p. 873-880, July/Aug. 2016 FOLIAR APPLICATION OF CALCIUM AND BORON IMPROVES THE SPIKE FERTILY AND YIELD OF WHEAT APLICAÇÃO FOLIAR DE CÁLCIO E BORO MELHORA A FERTILIDADE DA ESPIGA E PRODUTIVIDADE DO TRIGO Tiago ZOZ 1 ; Fábio STEINER 2 ; Edleusa Pereira SEIDEL 3 ; Deise Dalazen CASTAGNARA 4 ; Gabriel Elias de SOUZA 5 1. Professor, PhD., Mato Grosso do Sul State University – UEMS, Cassilândia, MS, Brazil. zoz@uems.br; 2. Professor, PhD., UEMS, Cassilândia, MS, Brazil. steiner@uems.br; 3. Professora, PhD., State University of Western Paraná – UNIOESTE, Marechal Cândido Rondon, PR, Brazil; 4 Professor, PhD., Federal University of Pampa – UNIPAMPA, Uruguaiana, RS, Brazil; 5. Agronomist, Integrated Colleges of Ourinhos – FIO, Ourinhos, SP, Brazil. ABSTRACT: Foliar applications of calcium (Ca) and boron (B) could improve the fertilization of flowers and enhance the wheat yield. The effects of foliar spray of Ca and B on plant growth, grain yield and yield components of wheat were investigated in this study. Treatments consisted of 0, 1.8, 3.6, and 7.2 L ha–1 application of chelated fertilizer containing 125 g L–1 of Ca and 6 g L–1 of B (Omega Cabor II®), divided into two spray, the first one at tillering and the second at early bloom. The results revealed that foliar spray of Ca and B did not affect the stem diameter, peduncle length, spike length, hectoliter weight and thousand-grain mass of wheat. Maximum plant height and flag leaf insertion height was recorded with 4.0 L ha–1 application of foliar fertilizer (4% increase over control). The 7.2 L ha–1 application of foliar fertilizer increased significantly the number of spikelets per spike (9%), number of grains per spike (24%), grain mass per spike (28%), spike mass (14%), number of spikes m–2 (32%) and grain yield (30%) compared to the control. Foliar application of Ca and B improves growth, fertilization of flowers and the number of fertile tillers of wheat plants resulting in higher grain yield. KEYWORDS: Fertilization of flowers, Foliar fertilization. Plant nutrition. Tillering. Triticum aestivum. INTRODUCTION Calcium (Ca) and boron (B) are important nutrients for growth and development of plants and participate in several physiological processes in plants. Calcium is an essential part of the plant cell wall and necessary for new cell formation. It enhances resistance to bacterial and viral diseases (USTEN et al., 2006) and activates several enzyme systems that regulate leaf and root growth (MENGEL; KIRKBY, 2001). Boron contributes to cell wall strength and development, as well as being critical to cell division, fruit and seed development, sugar synthesis and transport, and hormone development (CAMACHO-CRISTÓBAL et al., 2008). Calcium and boron combined are essential to pollen grain germination and pollen tube elongation (KRICHEVSKY et al., 2007), which helps provide successful fertilization or pollination, preventing the abortion of flowers. However, the benefits of Ca and B application depend on a balance between Ca and B levels in the plant. According to Tariq and Mote (2007), low Ca and high B could be detrimental to plant growth and yield. Calcium and boron deficiency can occur in very weathered soils due to continuous cropping, soil erosion, leaching of exchangeable bases, reduction of soil organic matter, and adsorption by aluminum and iron (hydr)oxides (STEINER; LANA, 2013; LANA et al., 2013). Boron plays a key role in root function and low B levels reduce the plant's ability to uptake water and nutrients from the soil, which often induces a Ca deficiency (TARIQ; MOTE, 2007). Foliar application of B is preferred over soil application because of the relatively narrow range from deficient to toxic levels (TRAUTMANN et al., 2014). Effectiveness of foliar spray depends on the nutrient uptake rate by leaves and its translocation into the plant (FERNÁNDEZ; BROWN, 2013). Foliar uptake and translocation of nutrient for other plant parts can be influenced positively or negatively by a series of factors, such as source used, plant species, application time. Chelated fertilizers have been developed to increase nutrient utilization efficiency. Calcium and boron applied by the foliar spray is transported in the phloem preferably for new tissues, with the movement linked to metabolic activity of plants. However, despite the importance of these nutrients, the foliar application of Ca and B shows conflicting and inconclusive results. Weaver et al. (1985) found that applications of calcium nitrate and boric acid in common bean, during the opening of the first flowers, promoted higher retention of pods per plant and, consequently, increase in grain yield. Received: 01/04/15 Accepted: 20/01/16 874 Foliar application of calcium and boron… ZOZ, T. et al. Biosci. J., Uberlândia, v. 32, n. 4, p. 873-880, July/Aug. 2016 Significant increases on the grain yield with foliar application of Ca and B were also reported for soybean (BEVILAQUA et al., 2002; SOUZA et al., 2008) and for common bean (FARINELLI et al., 2006). On the other hand, Silva et al. (2006) found no effect of foliar fertilization with calcium (500 g ha–1 of Ca) and boron (60 g ha–1 of B) on the yield components and grain yield of common bean. Seidel and Basso (2012) found that 3.0 L ha–1 application of foliar fertilizer containing 100 g L–1 of Ca and 5 g L–1 of B at different growth stages of soybean also did not affect the retention of pods and grain yield of the crop. However, the effect of foliar application of Ca and B on the grain yield of wheat (Triticum aestivum L.) are still unknown. Wheat is an important winter cereal crops from Brazil considering its use for food, animal feed or forage, seed industries, and other industrial purposes. The objective of this study was to investigate the effect of foliar spray of calcium and boron on plant growth, grain yield and yield components of wheat. The hypothesis is that early bloom applications of Ca and B could improve the fertilization of flowers and wheat yield. MATERIAL AND METHODS The experiment was carried out in Maripá, Paraná, Brazil (24º22' S, 53°44' W, altitude of 380 m). The soil was a clayey Rhodic Hapludox (Red Latosol in the Brazilian classification), with 775 g kg–1 of clay, 125 g kg–1 of silt, and 100 g kg–1 of sand. Before starting the experiment, soil samples were taken from the surface layer (0–0.20 m), air- dried, sieved through a 2.0 mm mesh, and analyzed according to Embrapa (2009). Soil chemical analysis showed pH in CaCl2 0.01 mol L –1 of 5.0, 28 g dm–3 of organic matter, 15 mg dm–3 of P (Mehlich-1), 5.4 cmolc dm –3 of H+Al, 0.7 cmolc dm – 3 of K, 7 cmolc dm –3 of Ca, 1.5 mmolc dm –3 of Mg, 14.7 cmolc dm –3 of CEC, 63 % of soil base saturation, 15 mg dm–3 of Cu (Mehlich-1), 1.8 mg dm–3 of Zn (Mehlich-1), and 0.25 mg dm–3 of B (water heated). The area has been cultivated in no- till since 1996 and the area was planted to soybean/maize and soybean/wheat, in the harvests 2006/07 and 2007/08, respectively. The regional climate, according to Köppen classification, is Cfa, humid subtropical (mesothermal), with warm summers and a tendency towards high rainfall concentration (mean temperature above 22 °C) and winter with infrequent frosts (mean temperature below 18 °C) with no defined season, and mean annual rainfall of 1,500 mm. Rainfall data during the experiment are shown in Figure 1. 0 10 20 30 40 50 60 70 31 April.2008 May.2008 June.2008 July.2008 August.2008 R ai nf al l ( m m d ay -1 ) Sw Hw1st 2nd Figure 1. Daily rainfall between April and August 2008 in Maripá, State of Paraná, Brazil. Sw – wheat sowing, 1st and 2nd – first and second foliar spray, respectively, Hw – wheat harvest. Wheat [Triticum aestivum L., cv. CD 104] was sown on April 26, 2008, in rows 0.15 m apart at a density of 350 seeds m–2. Fertilization was carried out by applying 20 kg ha–1 of N, 100 kg ha–1 of P2O2 and 100 kg ha–1 of K2O at sowing, and 80 kg ha –1 of N topdressing at the beginning of plants’s tillering as urea. Pests and diseases control was carried out with two applications of methamidophos (120 g a.i. ha–1), lufenuron (5 g a.i. ha–1) and azoxystrobin + cyproconazole (60 g a.i. ha–1 + 24 g a.i. ha–1). The experimental design was randomized blocks with five replications. Treatments consisted of four rates of Omega Cabor II® chelated fertilizer (125 g Ca L–1 and 6 g B L–1), divided into two spray, 875 Foliar application of calcium and boron… ZOZ, T. et al. Biosci. J., Uberlândia, v. 32, n. 4, p. 873-880, July/Aug. 2016 the first at tillering (18 days after plants emergence) and second at early bloom (65 days after plants emergence). The rates used were: (1) control (without spray); (2) 1.8 L ha–1 of foliar fertilizer (225 g ha–1 of Ca + 10.8 g ha-1of B); (3) 3.6 L ha–1 of foliar fertilizer (450 g ha–1 of Ca + 21.6 g ha–1 of B); and (4) 7.2 L ha–1 of foliar fertilizer (900 g ha–1 of Ca + 43.2 g ha–1 of B). The rates corresponded to 50%, 100% and 200% of the recommended rate (3.6 L ha–1) for the wheat crop. Applications were performed with a CO2 pressurized sprayer with 0.8 MPa working pressure capacity, equipped with flat fan nozzle, adjusted to apply 165 L ha–1 broth. The plants were sprayed at dusk due to a lower likelihood of drift by wind speed reduction and higher relative humidity. After spray, a minimum period of 72 hours without rain was observed, enabling the best use of the product. Each experimental plot consisted of eight 6.0 m long rows, considering the six central lines as floor area, ignoring 1.0 m from the ends of each row. Wheat was harvested when it reached physiological ripeness. Agronomic characteristics of the crop were assessed against the following variables: plant height, flag leaf insertion height, stem diameter, peduncle length, spike length, number of spikelets per spike, number of grains per spike, spike mass, grain mass per spike, number of spikes per square meter, hectoliter weight (HW), thousand grain mass and grains yield corrected to 130 g kg–1 water content. Data were submitted to analysis of variance and regression, both at the 0.05 level of confidence by F test. The significant equations with the higher coefficient of determination were adjusted. All analyses were performed using SigmaPlot 11.0 software for Windows (Systat Software, Inc., San Jose, CA, USA). RESULTS AND DISCUSSION Foliar application of calcium and boron did not affect the stem diameter, peduncle length and spike length. The stem diameter, peduncle length and spike length were 3.90±0.24 mm, 15.1±1.80 cm, 8.92±2.08 cm, respectively. These agronomic characteristics are predominantly determined by genetic factors, intrinsic to the cultivar, being little affected by environmental factors. The hectoliter weight and thousand grain mass of wheat were also not affected by foliar application of Ca and B. Hectoliter weight and thousand grain mass were 79.6±0.8 g and 46.2±4.2 g, respectively. The plant height and flag leaf insertion height increased significantly with foliar application of Ca and B (Figure 2). The maximum plant height (82.6 cm) and flag leaf insertion height (60.0 cm) were recorded with the 4.0 L ha–1 application of foliar fertilizer. Kappes et al. (2008) reported similar results for soybean crop, who found that foliar application of B increased the mean plant height. This increase in plant height of wheat with the Ca and B application is related to the functions of these nutrients on several physiological processes in the plants. y = 79.5 + 1.53x – 0.19x2 R² = 0.69* CV (%) = 2.5 60 65 70 75 80 85 90 0 1,8 3,6 5,4 7,2 P la nt h ei g ht ( cm ) A. 1.8 3.6 5.4 7.2 y =57.4 + 1.27x – 0.16x2 R² = 0.72* CV (%) = 2.4 40 45 50 55 60 65 70 0 1,8 3,6 5,4 7,2 F la g l ea f in se rt io n h ei g ht ( cm ) B. 1.8 3.6 5.4 7.2 Ômega Cabor II® fertilizer rates (L ha–1) Figure 2. Effect of foliar spray of Omega Cabor II® chelated fertilizer (125 g L–1 of Ca and 6 g L–1 of B) on the plant height (A) and flag leaf insertion height (B) of wheat (Triticum aestivum L.). *: statistical significance at 5% by F test. CV: coefficient of variation. Calcium participates as messenger in metabolic processes related to growth and development of plants, such as cell division, differentiation and elongation (HEPLER, 2005), and 876 Foliar application of calcium and boron… ZOZ, T. et al. Biosci. J., Uberlândia, v. 32, n. 4, p. 873-880, July/Aug. 2016 activate several enzyme systems that regulate leaf and root growth (MENGEL; KIRKBY, 2001). In turn, the B is essential for cell wall formation and it plays an important role in the development and growth of new cells (CAMACHO-CRISTÓBAL et al., 2008). In addition, this element also regulates the production of auxin in the plants. Auxin is a plant hormone that among other functions is responsible for elongation and cell division and growth of the plant (MENGEL; KIRBY, 2001). Therefore, the adequate supply of Ca and B is very important for growth and development of plants. The number of spikelets per spike and number of grains per spike increased progressively with increasing rates of foliar fertilizer containing 125 g L–1 of Ca and 6 g L–1 of B (Figure 3A and 3B). The number of spikelets per spike increased from 17.8 units in the control to a maximum of 19.5 units with 7.2 L ha–1 application of foliar fertilizer, indicating mean increase of 9% (Figure 3A). The number of grains per spike increased from 43.9 units in the control to a maximum of 54.6 units with 7.2 L ha–1 application of foliar fertilizer, indicating mean increase of 24% (Figure 3B). This increase in the number of grains per spike indicates that the Ca and B application improved the fertilization of flowers, reducing the abortion of flowers. Weaver et al. (1985) found that foliar application of Ca and B resulted in higher retention of pods per plant of common bean. Similarly, Tahir et al. (2009) also found that foliar B application at different growth stages increased the number of grains per spike of wheat. Calcium and boron deficiency can interfere in the germination of pollen grains and growth of pollen tubes (KRICHEVSKY et al., 2007), resulting in the reduction of the number of grains per spike. According to Rosolem et al. (1990), there is high negative correlation between the Ca concentration in the plant and number of flowers or pods aborted. Tahir et al. (2009) reported that B deficiency impairs grain setting in wheat, resulting in increased number of open spikelets and decreased number of grains per spike. Foliar application of Ca and B resulted in significant increase of the grain mass per spike and spike mass of wheat. The grain mass per spike and spike mass increased from 1.42 and 3.48 g in the control treatment to a maximum of 1.82 and 3.98 g with 7.2 L ha–1 application of foliar fertilizer, indicating mean increase of 28 and 14%, respectively (Figure 3C and 3D). The increase in the grain mass per spike and spike mass was due to increased number of grains per spike obtained with to the foliar fertilizer rates (Figure 3B). The number of spikes per unit area was affected by foliar application of Ca and B (Figure 3E). The number of wheat spikes per unit area increased from 228 spikes m–2 in the control treatment to a maximum of 301 spikes m–2 with 7.2 L ha–1 application of foliar fertilizer, indicating mean increase of 32%. The increase in the number of spikes per unit area was due to the higher number of fertile tillers per plant at the end of crop cycle. Ahmad and Irshad (2011) verified that B application increased in 15% the number of tillers per plant of wheat. The reason for increased number of tillers per plant seems to be presence and utilization of B at required stages of plant growth. Boron insufficiency may results in retarded growth, increase in aborted tillers, and suppressed grain yield per tiller (TAHIR et al., 2009). Boron deficiency in cereals may reduce the number of tillers per plant mainly because it makes the thinner stems and shorter and fewer tillers (DUNN et al, 2005). The number of fertile tillers are very important to wheat crops because the higher number of fertile tillers per area, the higher grain yield. Number of fertile tillers in wheat is more important instead of total number of tillers because the increase in yield is only determined due to increase in fertile tillers (TAHIR et al., 2009). Effect of B application on fertile tillers are in agreement with those reported by Khan et al. (2006) and Ahmad and Irshad (2011), who showed that B application had significant effect on fertile tillers of rice and wheat, respectively. The grain yield of wheat increased progressively with increasing rates of foliar fertilizer (Figure 3F). The percentage increase of grain yield was 30%, when comparing the wheat yield without foliar spray (2,037 kg ha–1) and with 7.2 L ha–1 application of foliar fertilizer (2,650 kg ha–1). There was mean increase of 85 kg ha–1 of wheat grains for each liter per hectare of foliar fertilizer applied. The higher grain yield of wheat with foliar application of Ca and B was due to the increased in the number of grains per spike (Figure 3B) and number of spikes per unit area (Figure 3E), provided by the increased in the fertilization of flowers and number of fertile tillers per plant, respectively. Positive effects of Ca and B application on grain yield are in agreement with those reported by Souza et al., (2008), Farinelli et al. (2006), Bevilaqua et al. (2002), and Weaver et al. (1985), who found that foliar application of Ca and B increased the grain yield of soybean and common bean crops. On the other hand, Seidel and Basso (2012) and Silva et al. (2006) found no effect of 877 Foliar application of calcium and boron… ZOZ, T. et al. Biosci. J., Uberlândia, v. 32, n. 4, p. 873-880, July/Aug. 2016 foliar fertilization of Ca and B on the yield components and grain yield of soybean and common bean, respectively. Effects of foliar application of Ca B on grain yield are related to the availability of these nutrients in the soil. In this study, the levels of available Ca (7.0 cmolc dm –3 of Ca) and B (0.25 mg dm–3 of B) in the soil were in the availability classes high and medium, respectively (RAIJ et al., 1997). y = 17.8 + 0.23x R² = 0.97* CV (%) = 4.6 10 12 14 16 18 20 22 0 1,8 3,6 5,4 7,2 S p ik el et s p er s p ik e (u n it s) A. 1.8 3.6 5.4 7.21.8 y =43.9 + 1.48x R² = 0.98** CV (%) = 5.9 20 25 30 35 40 45 50 55 60 0 1,8 3,6 5,4 7,2 G ra in s p er s pi k e (u n it s) B. 1.8 3.6 5.4 7.21.8 y = 1.42 + 0.056x R² = 0.96* CV (%) = 2.9 0 0,4 0,8 1,2 1,6 2 0 1,8 3,6 5,4 7,2 G ra in m as s p er s p ik e (g ) C. 1.8 3.6 5.4 7.2 0.4 0.8 1.2 1.6 2.0 1.8 y = 3.48 + 0.070x R² = 0,98** CV (%) = 5.6 0 1 2 3 4 5 0 1,8 3,6 5,4 7,2 S p ik e m as s (g ) D. 1.8 3.6 5.4 7.21.8 y = 228.0 + 10.2x R² = 0.76** CV (%) = 14.3 0 50 100 150 200 250 300 0 1,8 3,6 5,4 7,2 S pi k es p er s qu ar e m et er ( un it s) E. 1.8 3.6 5.4 7.2 y =2037 + 85.2x R² = 0.96** CV (%) = 5.2 0 500 1000 1500 2000 2500 3000 0 1,8 3,6 5,4 7,2 G ra in y ie ld ( k g h a– 1 ) F. 1.8 3.6 5.4 7.2 Ômega Cabor II® fertilizer rates (L ha–1) Figure 3. Effect of foliar spray of Omega Cabor II® chelated fertilizer (125 g L–1 of Ca and 6 g L–1 of B) on the number of spikelets per spike (A), number of grains per spike (B), grain mass per spike (C) spike mass (D), number of spikes per square meter (E) and grain yield (F) of wheat (Triticum aestivum L.). * and **: statistical significance at 5% and 1%, respectively, by F test. CV: coefficient of variation. In general, the results presented here confirm the hypothesis established initially and suggest that early bloom applications of Ca and B are key components of pollen tube elongation that help ensure more successful fertilization of flowers and higher wheat yields. In this study, the improvement in fertilization of the wheat flowers was evidenced by the increase in the number of 878 Foliar application of calcium and boron… ZOZ, T. et al. Biosci. J., Uberlândia, v. 32, n. 4, p. 873-880, July/Aug. 2016 spikelets per spike, number of grains per spike, grain mass per spike and spike mass (Figure 3). Another important yield component for the increase in grain yield of wheat reported in this study was the number of fertile tillers per area (Figure 3E), which determines the amount of spikes harvested per area. CONCLUSION Foliar application of calcium and boron improves growth, fertilization of flowers and the number of fertile tillers of wheat plants resulting in increased grain yield. RESUMO: A aplicação foliar de cálcio (Ca) e boro (B) pode garantir a fertilização das flores e aumentar a produtividade do trigo. Este estudo teve como objetivo avaliar o efeito da aplicação foliar de Ca e B no crescimento, nos componentes de rendimento e na produtividade do trigo. Os tratamentos constituíram da aplicação de 0; 1,8; 3,6 e 7,2 L ha–1 de fertilizante foliar, na forma de quelato, contendo 125 g L–1 de Ca e 6 g L–1 de B (Omega Cabor II®), divididas em duas aplicações foliares, a primeira no início do afilhamento e a segunda no emborrachamento. Os resultados revelaram que a aplicação foliar de Ca e B não afetaram o diâmetro de colmo, comprimento do pedúnculo, comprimento da espiga, peso do hectolitro e massa de mil grãos de trigo. A maior altura de planta e altura de inserção da folha bandeira foram verificados com a aplicação de 4.0 L ha–1 de fertilizante foliar (aumento de 4% em relação ao controle). A aplicação de 7.2 L ha–1 de fertilizante foliar aumentou significativamente o número de espiguetas por espiga (9%), número de grãos por espiga (24%), massa de grãos por espiga (28%), massa de espiga (14%), número de espigas m–2 (32%) e produtividade de grãos (30%). 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