Microsoft Word - 7-Agra_33082 314 Original Article Biosci. J., Uberlândia, v. 33, n. 2, p. 314-320, Mar./Apr. 2017 IRRIGATION AND NITROGEN MANAGEMENT IN PROTEIN CONTENT AND QUALITY OF COMMON BEAN SEEDS MANEJO DA IRRIGAÇÃO E NITROGÊNIO NO TEOR DE PROTEÍNA E QUALIDADE DE SEMENTES DE FEIJÃO Matheus Gustavo da SILVA¹; Aliston Flávio de SOUZA¹; Gustavo Henrique Ferreira da SILVA¹; Adriano da Silva LOPES¹; Paulo Eduardo TEODORO² 1. Universidade Estadual do Mato Grosso do Sul, Unidade Universitária de Aquidauana, MS, Brasil; 2. Universidade Federal do Mato Grosso do Sul, Campus de Chapadão do Sul, MS, Brazil. eduteodoro@hotmail.com ABSTRACT: The aim of this study was to investigate the influence of different irrigation managements and nitrogen topdressing rates on the protein content and physiological quality of common bean seeds. Trial was conducted at Universidade Estadual de Mato Grosso do Sul, Unidade Universitária de Aquidauana from June to September, 2010. Experimental design was a randomized block in a split plot, using three blocks and two replications within each block. Plots corresponded to three irrigation managements: Hargreaves-Samani, Penman-Montheith and Class A pan. Subplots were represented by four N topdressing rates (zero, 50, 100 and 150 kg ha-1). The following variables were evaluated: 100- seed mass, nitrogen and crude protein content in seeds, germination at field, germination at laboratory, accelerated aging and germination speed index. There was a significant interaction between the different irrigation management and nitrogen topdressing rates for nitrogen and crude protein content in seeds, germination at laboratory and emergence speed index. Levels between 70 and 120 kg ha-1 N in conjunction with irrigation management by Hargreaves-Samani method provide better physiological quality of common bean seeds. KEYWORDS: Phaseolus vulgaris. Germination. Vigor tests. INTRODUCTION Common bean (Phaseolus vulgaris L.) plays an important role in Brazilian food as it constitutes the main source of vegetable protein, especially for low-income people, even being a source of iron, carbohydrates and fiber (GOMES JUNIOR et al., 2005). In Brazil, common bean has been grown on a large diversity of production systems, achieving yields higher than 4000 kg ha-1 under irrigation systems (FARINELLI et al., 2006), however, these figures do not reflect the overall average of domestic production, which is currently of 939 kg ha-1 (CONAB, 2013). According to Farinelli et al. (2006), one of the main reasons for the low national average yield is the use of seeds with lower quality, which results from the interaction of genetic, physical, sanitary and physiological components, this latter being influenced by the environment in which the seeds are produced (CARVALHO; NAKAGAWA, 2000). Physiological quality is related to the seeds ability to perform its vital functions, characterized by longevity, germination and vigor. Thus, the effects on quality are generally translated by a decrease in germination percentage, increased abnormal seedling and reduced seedling vigor (TOLEDO et al., 2009). In Brazil, fertilization with nitrogen (N) as topdressing is a practice that has provided increments on the physiological quality and protein content of common bean seeds (BORDIN et al., 2003; GOMES JUNIOR et al., 2005; FARINELLI et al., 2006; TOLEDO et al., 2009; GOMES JUNIOR et al., 2010). The nutrient wich the common bean absorbs the most is N, being necessary for the chlorophyll synthesis as part of this molecule is involved in the photosynthesis. In addition, the N participates of the amino acid composition, having a direct effect on protein content in the seeds (GOMES JUNIOR et al., 2005). However, another variable that must be analyzed together with the nitrogen topdressing is the irrigation management, since this practice is commonly used in the common bean crop. Pacheco et al. (2012) report besides being the main factor responsible for the common bean cultivation in the winter, the irrigation also allows this culture to express its productive potential. Thus, the aim of this study was to evaluate the influence of different irrigation managements and nitrogen topdressing rates on the protein content and physiological quality of common bean seeds. MATERIAL AND METHODS Trial was carried out at Universidade Estadual de Mato Grosso do Sul, Unidade Universitária de Aquidauana (20°20’S, 55°48’W and average altitude of 174 m), from June to Received: 03/02/16 Accepted: 05/11/16 315 Irrigation and nitrogen management… SILVA, M. G. et al. Biosci. J., Uberlândia, v. 33, n. 2, p. 314-320, Mar./Apr. 2017 September 2010. The climate, according to Köppen classification is Aw, defined as hot sub-humid tropical climate, with rainy season in summer and dry in winter (ALVARES et al., 2014). Accumulated rainfall, average temperature and relative humidity, during the trial, were 18.61 mm, 23.1ºC and 56.9%, respectively. The soil was classified by Schiavo et al. (2010) as Ultisol dystrophic, physically deep and moderately drained, whose chemical properties are shown in Table 1. Table 1. Experimental area chemical soil analysis. Aquidauana, MS, 2010. Layer pH P OM K Ca Mg Al H+Al S T V (m) (H2O) mg dm -3 --------------mmolc dm -3-------------- (%) 0.0 – 0.2 5.4 56.6 27.1 4.80 44 10 0.0 33 58.8 91.8 64.1 0.2 – 0.4 6.9 40.5 16.8 2.00 51 6 0.0 14 59.0 73.0 80.8 OM: organic matter. Experimental design was a randomized block in split plot, using three blocks and two replications within each block. The plots corresponded to three irrigation management based on reference evapotranspiration (ETo) estimate methods. Subplots were represented by four N topdressing rates (0, 50, 100 and 150 kg ha-1). Irrigation management consisted by: a) Hargreaves-Samani method (HS): developed in California, in semi-arid conditions, from data obtained in lysimeters with grass and described according to equation (PEREIRA et al., 1997): ETo(HS) = 0.0135 kt Ra (Tmax - Tmin) 0.5 (T + 17.8), wherein ETo(HS) = reference evapotranspiration, according to HS method (mm d- 1); kt = empirical coefficient, used in continental regions (0.162); Ra = extraterrestrial radiation (mm d-1); T = average air temperature (ºC); Tmax = maximum air temperature (ºC); e Tmin = minimum air temperature (ºC). b) Penman-Montheith method FAO-56 (PM): recommended by FAO, with stomatal resistance of 70 m s-1, grass height fixed at 0.12 m and albedo of 23%, whose estimate is given using the following equation 2 (ALLEN et al., 1998): )0.34Uγ(1∆ ea)(es 273T 900U γG)(Rn0.408∆ ETo 2 2 (PM) ++ −      + +− = , wherein ETo(PM) = reference evapotranspiration, by PM method (mm d-1); Rn = net radiation (MJ m-2 d- 1); G = heat flow in the soil (MJ m-2 d-1); D = water vapor saturation curve declination (kPa ºC-1); U2 = average wind speed, 2.0 m above the soil surface (m s-1); T = average air temperature (ºC); es = vapor saturation pressure (kPa); ea = vapor current pressure (kPa); and g = psychrometric constant (kPa ºC-1). c) Class A pan method (CAP): consisting of a cylindrical pan with galvanized steel sheet with 1.21 m in diameter and 0.255 m deep, aluminized color, placed on top of a wooden pallet and positioned 15.0 cm from the soil in grassy area, with edge 10.0 m. Water was placed inside the pan, the level being measured in a reassuring pit of 0.25 m height and 0.1 m diameter, whose edge was affixed to a micrometer screw, measuring the minimum variations up to 0.01 mm water evaporation. At the pit bottom, there is an orifice that allows the entry of water, for carrying out measurements (ALLEN et al., 1998). The equation used for this method is: ETo(TCA) = kp ECA, wherein ETo(TCA) = reference evapotranspiration, by CAP method (mm d-1); ECA = evaporation observed in CAP (mm d-1); and kp = pan coefficient (0.75). The kp, as constant of 0.75, was extracted from table proposed by Allen et al. (1998), considering the wind speed lower than 2.0 m s-1 and relative humidity between 40% and 70%. The crop evapotranspiration was determined using the dry bean coefficient, which varied according to its phenology, vegetative stage being 0.35 to 1.15, the reproductive phase of 1.15 and the phase comprising the filling grains and the maturity of 1.15 and 0.25 (ALLEN et al., 1998). Crop evapotranspiration was calculated using the equation: ETc = ETo kc, which ETc = crop evapotranspiration (mm d-1); ETo = reference evapotranspiration (mm d-1) and kc = crop coefficient (adimensional). Conventional sprinkler irrigation system was installed on June 11, 2010, three days after sowing of common bean. For performing the three irrigation management, the area was divided into three blocks of 84.0 x 24.0 m, 12.0 m spaced. The plots were 24.0 x 24.0 m, spaced apart by 6.0 m in the same block. Inside the plots, there were four sub plots containing N topdressing rates, with two replications, totaling eight subplots of three lines (0.45 mx 5.0 m), covering an area of 6.75 m². The results for irrigation management are shown in Table 2. 316 Irrigation and nitrogen management… SILVA, M. G. et al. Biosci. J., Uberlândia, v. 33, n. 2, p. 314-320, Mar./Apr. 2017 Table 2. Maximum (ETcmax), average (ETcmed) and minimum (ETcmin) evapotranspiration, irrigation blade (IB), total blade (TB) and irrigation frequency (IF) depending on the irrigation management over the common bean cycle grown in Aquidauana, MS, 2010. Irrigation management ETcmax ETcmed ETcmin IB TB IF -------------------mm day-1------------------- ---mm--- days HS 6.55 3.47 0.76 282.40 301.21 4.76 PM 6.35 3.09 0.79 245.60 264.41 5.34 CAP 11.21 4.45 0.83 380.60 399.41 3.71 It was held weed desiccation with the application of 360 g ha-1 active ingredient glyphosathe in a spray volume of 300 L ha-1 of commercial product. Common bean was sown mechanically on June 8, 2010, winter period, using the Pérola cultivar, with 0.45 m between rows and 16 plants m-1. Base fertilization occurred at the time of sowing and consisted of 240 kg ha-1 formulated 04-20-20. For weed control in post-emergence, it was carried out at 20 days after crop emergence application of active and selective ingredients fluazifop-p-butyl + fomesafen at 125 + 125 g ha-1 with the 300 mL ha-1 of commercial product according to Silva et al. (2015). Topdressing occurred when the plants were in V4 stage, as urea (45% N), in the respective rates. At the time of full flowering of common bean (R6 stage), the two central rows of each subplot were collected. After harvesting and manual threshing, the seeds were stored in laboratory for following assessments: 100-seed mass: determined by the one hundred seeds mass, randomly chosen from the total sample of each subplot with their values being adjusted to 13% moisture; Germination: 200 seeds were used for each subplot, divided into four sub-samples of 50 seeds. They have been deposited on paper towels (RP), moistened with water equivalent to 2.5 times the substrate weight, and maintained at temperature of 25°C, being evaluated the normal seedlings on the fifth and ninth days after the test facility (BRASIL, 2009). Germination speed index: was made together with the germination tests, where from the fifth day after assembling the test was made by counting the number of germinated seeds, the same being repeated daily until the ninth day. Germination speed index was calculated according to Maguire (1962), represented by formula: IVG = G1/ N1 + G2/ N2 + ...... Gn/ Nn, wherein G1, G2 and Gn is the number of germinated diaspores and N1, N2 and Nn, is the number of days after sowing. Seedling emergence at field: it used 200 seeds (four repetitions with 50 seeds) per treatment, sown in furrows, with line spacing of 0.50 m, at a depth of 0.04 m. Counting was made considering the total number of emerged plants 21 days after sowing (VIEIRA; CARVALHO, 2004). Accelerated aging: 200 seeds from each subplot were used, divided into four subplots with 50 seeds (repetitions), employing Gerbox plastic boxes with individual compartment (mini-chambers) having therein a stainless steel screen tray on which were placed 50 seeds. On plastic boxes were added 40 ml of distilled water, which were closed and kept at 42°C for 72 h (MARCOS FILHO, 1999). Total nitrogen and crude protein content in seeds: a sample of 20 g of seeds was removed from the total mass of seeds obtained in each subplot. These seeds were milled in centrifugal mills, with the sieve of 0.2 mm in diameter. Subsequently, the nitrogen content in seeds was determined according to the Kjeldahl method. With the total nitrogen content in the seeds, it used the conversion factor of 6.25 for the calculation of crude protein present in seeds (TEDESCO et al., 1995). Variables analyzed were submitted to the Shapiro-Wilk’s test to verify the residuals normality and subsequently submitted to analysis of variance. Qualitative factor (irrigation management) was submitted to the means comparison by Tukey’s test and quantitative (N topdressing rates) to polynomial regression analysis. The best fitted equation was chosen according to the coefficient of determination and the regression coefficients significance was tested by the t-test and corrected based on the residues from the analysis of variance. All analyzes were performed with Sisvar statistical software (FERREIRA, 2011). RESULTS AND DISCUSSION There was a significant interaction between the different irrigation management and nitrogen topdressing rates for nitrogen and crude protein content in seeds, germination at laboratory and emergence speed index (Table 3). The 100-seed mass was not affected by any study factor, possibly because this variable is related to genotypic cultivar 317 Irrigation and nitrogen management… SILVA, M. G. et al. Biosci. J., Uberlândia, v. 33, n. 2, p. 314-320, Mar./Apr. 2017 features, having lower variation percentage resulting from the changes in the cultivation (CRUSCIOL et al., 2003). On the other hand, the germination at field showed quadratic adjustment in response to N rates, reaching maximum point with the 100 kg ha-1 approximate rate. Similar results were achieved by Oliveira et al. (2003), who observed quadratic adjustments to this variable in response to N rates. Tabela 3. Calculated F values and coefficient of variation (CV) for 100-seed mass (HSM), nitrogen content in seeds (NS), crude protein content in seeds (CPS) germination at field (GF), germination at laboratory (GL), accelerated aging (AA) and germination speed index (GSI) of common bean according to the different irrigation management (I) and nitrogen rates (N). Variable Irrigation management (I) Nitrogen rates (N) I x N CV (%) HSM 2.6ns 0.5ns 1.7ns 7.2 NS 27.7** 1.1ns 9.8** 6.9 CPS 27.7** 1.1ns 9.8** 7.2 GF¹ 1.1ns 4.7** 1.2ns 10.9 GL 5.3* 1.6ns 2.6* 6.5 AA 12.4** 1.0ns 1.1ns 31.6 GSI 9.6* 1.6ns 2.5* 6.4 ns, *, **: not significant, significant at 5 and 1% probability by F test, respectively; ¹Y= 77.6 + 0.228GF – 0.001x²; R²= 0.99. For unfolding the irrigation management within each N rate, Penman-Monteith provided the highest N content in the seeds, regardless of the N topdressing rate. For unfolding N rates within each irrigation management, Hargreaves-Samani and Penman-Monteith provided quadratic adjustments to nitrogen content in the seeds (Table 4), being the maximum contents obtained with 94 and 72 kg ha-1 N, respectively, but there was no adjustment of this variable to N rates when used management by Class A pan. These results differ from those obtained by Farinelli et al. (2006), who assessing the physiological quality of common bean seeds in response to N rates did not observe increase in N content in the seeds, probably because in these studies there was no increase in N content in the plant. Table 4. Unfolding of significant interaction between irrigation management and nitrogen topdressing rates for nitrogen and crude protein content in seeds, germination at laboratory and germination speed index in common bean seeds. Irrigation management N rates (kg ha-1) Equation R2 0 50 100 150 Nitrogen contente in seeds (%) HS 4.1 b 4.0 c 5.2 a 4.2 b Y= 3.9 + 0.0151x – 0.00008x2 0.32 PM 5.7 a 5.8 a 4.9 a 6.2 a Y= 5.9 – 0.0172x + 0.00012x2 0.44 CAT 4.3 b 4.7 b 4.3 b 4.5 b ----- --- Crude protein content in seeds (%) HS 25.6 b 24.7 c 32.4 a 26.5 b Y= 24.5 + 0.0945x – 0.0004x2 0.32 PM 35.9 a 36.2 a 30.7 a 38.5 a Y = 36.9 – 0.1077x + 0.0007x2 0.44 CAP 26.8 b 29.2 b 26.6 b 28.0 b ----- --- Germination at laboratory (%) HS 88 90 95 a 91 ab Y = 89.5 – 0.06x 0.66 PM 92 97 85 ab 94 a ----- --- CAP 91 87 80 b 83 b ----- --- Germination speed index HS 8.6 8.9 ab 9.4 a 8.9 a ----- --- PM 9.1 9.7 a 8.5 ab 9.3 a ----- --- CAP 8.7 8.5 b 7.8 b 7.9 b Y= 8.7 – 0.06x 0.80 HS: Hargreaves-Samani; PM: Penman-Monteith; CAT: Class A pan; Means followed by the same letter in the same column do not differ by Tukey’s test at 5% probability. 318 Irrigation and nitrogen management… SILVA, M. G. et al. Biosci. J., Uberlândia, v. 33, n. 2, p. 314-320, Mar./Apr. 2017 For unfolding the irrigation management within each N rate, Penman-Monteith resulted in higher crude protein content in seeds, regardless of the N topdressing rate. For unfolding N rates within each irrigation management, there were quadratic adjustments to the crude protein content in seeds with the use of Hargreaves-Samani and Penman- Monteith, being the maximum contents obtained with 118 and 77 kg ha-1 N, respectively; however, there was no adjustment of this variable to N rates when using the management by Class A pan. Similar results were obtained by Bordin et al. (2003), Gomes Junior et al. (2005), Toledo et al. (2009) and Gomes Junior et al. (2010), who found quadratic adjustment of crude protein in response to N topdressing rates, and the maximum contents achieved with rates between 70 and 120 kg ha-1 N. Moreover, these results indicate that different N rates promote increase in the N content in the common bean seeds, resulting in a higher crude protein content. This occurs because the N absorbed by the plant combines itself with carbon skeletons to produce proteins that are broken, translocated and stored in grains in the form of proteins and amino acids (GOMES JUNIOR et al., 2005). For unfolding the irrigation management within each N rate except control (0 kg ha-1 N), Penman-Monteith and Hargreaves-Samani promoted a higher percentage of germination at laboratory and emergency speed index. For unfolding N rates within each irrigation management, there were negative linear adjustments for germination at laboratory with the use of Hargreaves-Samani and for emergence speed index with use of Class A pan. It can be seen in Table 5 that the irrigation management by Penman-Monteith provided appropriate rates for the accelerated aging test. According to Dias and Marcos Filho (1995), this test causes degenerative changes in the metabolism of common bean seeds, triggering the disintegration and loss of integrity on the membrane system of the cell. Table 5. Average values of accelerated aging for different irrigation management in common bean. Irrigation managements (I) Accelerated aging (%) Hargreaves-Samani 48.4 b Penman-Monteith 71.8 a CAP 48.0 b Means followed by the same letter in the same column do not differ by Tukey’s test at 5% probability. Talking into account that the irrigation management by Penman-Monteith has also provided the highest values for N and for the crude protein content in the seeds, it is likely that with this management there was no reduction on the acid phosphatase and on the esterase enzymes activity. This was possibly due to the lower irrigation depth applied with this method (Table 2), which may have minimized the leaching of N and led to a greater uptake and nutrition by the plants, enhancing the inference performed by Lopes et al. (2011) that this method is the most accurate for estimating ETo, amongst the evaluated ones. CONCLUSIONS Irrigation management and nitrogen topdressing influences the nitrogen and crude protein content in seeds, germination at laboratory and germination speed index. Levels between 70 and 120 kg ha-1 N in conjunction with irrigation management by Hargreaves-Samani method provide better physiological quality of common bean seeds. RESUMO: O objetivo deste trabalho foi verificar a influência de diferentes manejos de irrigação e doses de nitrogênio (N) em cobertura sobre o teor de proteína e a qualidade fisiológica de sementes de feijão. O experimento foi conduzido na Universidade Estadual de Mato Grosso do Sul, Unidade Universitária de Aquidauana nos meses de junho a setembro de 2010. O delineamento experimental utilizado foi em blocos casualizados, em esquema de parcelas subdivididas, utilizando-se três blocos e duas replicações dentro de cada bloco. As parcelas corresponderam a três manejos de irrigação: Hargreaves-Samani, Penman-Montheith e Tanque Classe A. As subparcelas foram representadas por quatro doses de N aplicadas em cobertura (zero, 50, 100 e 150 kg ha-1). Foram avaliadas as seguintes variáveis: massa de cem grãos, teor de nitrogênio nas sementes, germinação a campo, germinação em laboratório, envelhecimento acelerado e 319 Irrigation and nitrogen management… SILVA, M. G. et al. Biosci. J., Uberlândia, v. 33, n. 2, p. 314-320, Mar./Apr. 2017 índice de velocidade de germinação. 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