Acessibilidade / Reportar erro

Gladiolus production and nutritional status as a function of silicon application to the substrate1

ABSTRACT

Gladiolus is among the most traditional and important cut flowers in Brazil. Silicon (Si) is an element that has increased the production and quality of some ornamental plants. This study aimed at evaluating the production and nutritional status of gladiolus cultivars under greenhouse conditions, according to the Si doses applied to the substrate. The experimental design was randomized blocks, in a 3 x 4 factorial scheme, being three gladiolus cultivars ('White Friendship', 'Rose Friendship' and 'Red Beauty') and four Si doses (0 mg dm-3, 150 mg dm-3, 300 mg dm-3 and 600 mg dm-3), with five replicates. Morphological traits and leaf Si, macro and micronutrients were evaluated. 'White Friendship' and 'Red Beauty' developed taller plants, with a higher diameter and spikes heavier and longer than 'Rose Friendship'. The order of leaf nutrient concentrations for all the cultivars evaluated was the same (K > N > Ca > Mg > S > P > Fe > Mn > B > Zn > Cu), with all of them being classified as Si non-accumulators. Neither the evaluated morphological variables, nor the uptake of the nutrients N, P, K, Ca, Mg, S, B, Cu, Fe, Mn and Zn, were affected by the Si supplementation, suggesting that the addition of Si to the substrate does not enhance the gladiolus production.

KEYWORDS:
Gladiolus x grandiflorus Hort.; ornamental plants; floriculture

RESUMO

Produção e estado nutricional de gladíolos em função da aplicação de silício ao substrato

O gladíolo encontra-se entre as mais tradicionais e importantes flores de corte, no Brasil. O silício (Si) é um elemento que tem aumentado a produção e qualidade de algumas plantas ornamentais. Objetivou-se avaliar a produção e o estado nutricional de cultivares de gladíolo em ambiente protegido, em função da aplicação de Si ao substrato. O delineamento experimental utilizado foi o de blocos ao acaso, em esquema fatorial 3 x 4, sendo três cultivares de gladíolo ('White Friendship', 'Rose Friendship' e 'Red Beauty') e quatro doses de Si (0 mg dm-3, 150 mg dm-3, 300 mg dm-3 e 600 mg dm-3), com cinco repetições. Foram avaliadas características fitotécnicas, além dos teores foliares de Si, macro e micronutrientes. 'White Friendship' e 'Red Beauty' produziram plantas mais altas, com maior diâmetro e hastes florais mais compridas e mais pesadas do que 'Rose Friendship'. A ordem do teor de nutrientes nas folhas das três cultivares foi a mesma (K > N > Ca > Mg > S > P > Fe > Mn > B > Zn > Cu), sendo todas elas classificadas como não acumuladoras de Si. A aplicação de Si não influenciou nenhuma variável fitotécnica avaliada e nem a absorção dos nutrientes N, P, K, Ca, Mg, S, B, Cu, Fe, Mn e Zn, sugerindo que a adição de Si ao substrato não aumenta a produção de gladíolos.

PALAVRAS-CHAVE:
Gladiolus x grandiflorus Hort.; plantas ornamentais; floricultura

INTRODUCTION

Gladiolus (Gladiolus x grandiflorus Hort.) is a bulbous herbaceous plant from tropical to subtropical climate. This ornamental crop is used in landscaping and gardening, cut-flower decorations and commercial production of bulbs for the Brazilian market and for exporting (Barbosa 2011BARBOSA, J. G. Palma-de-santa-rita (gladíolo): produção comercial de flores e bulbos. Viçosa: Ed. UFV, 2011.). It is an herbaceous plant with short life cycle and well adapted to Brazilian climatic conditions. Because of that, the production costs are relatively low, with a rapid return on investments.

According to the classical definition of essentiality, silicon (Si) is not considered essential for plant nutrition. Nevertheless, it is often applied to crops because it provides several beneficial effects, such as upright leaves with higher photosynthetic capacity, increased chlorophyll content, reduced transpiration and loss of water, increased mechanical resistance of tissues and better resistance to diseases and pests (Epstein & Bloom 2005EPSTEIN, E.; BLOOM, A. J. Mineral nutrition of plants: principles and perspectives. Sunderland: Sinauer Associates, 2005.).

Silicon is absorbed by plants as silicic acid (H4SiO4) and translocated via xylem. It is mostly accumulated in areas of maximum transpiration, such as leaves, trichomes and spines, in the form of hydrated amorphous silica (SiO2.nH2O), which prevents or reduces its mobility in the phloem (Currie & Perry 2007CURRIE, H. A.; PERRY, C. C. Silica in plants: biological, biochemical and chemical studies. Annals of Botany, v. 100, n. 7, p. 1383-1389, 2007., Taiz & Zeiger 2013TAIZ, L.; ZEIGER, E. Fisiologia vegetal. 5. ed. Porto Alegre: Artmed, 2013.).

Silicon supplementation to composite substrates that contain little available Si, such as organic and sand substrates, is reported to have positive effects on plants (Zanão Júnior et al. 2013ZANÃO JÚNIOR, L. A. et al. Produção de rosas influenciada pela aplicação de doses de silício no substrato. Revista Brasileira de Ciência do Solo, v. 37, n. 6, p. 1611-1619, 2013.). The main positive effects also include flowers with better quality and greater longevity (Jana & Jeong 2014JANA, S.; JEONG, B. R. Silicon: the most under-appreciated element in horticultural crops. Trends in Horticultural Research, v. 4, n. 1, p. 1-19, 2014.). Carvalho et al. (2013)CARVALHO, P. R. et al. Efeito do silício na qualidade de flores de Dendrobium nobile (Orchidaceae). Semina: Ciências Agrárias, v. 34, n. 4, p. 1615-1622, 2013. found that the application of Si to the Dendrobium nobile orchid increased flower production and longevity. Ornamental plants, such as aster, clove, chrysanthemum, geranium, sunflower, petunia, rose, vinca and zinnia, accumulate Si in their tissues in amounts ranging 0.21-32.8 g kg-1, depending on the species (Carvalho et al. 2009CARVALHO, M. P. et al. Silício melhora produção e qualidade do girassol ornamental em vaso. Ciência Rural, v. 39, n. 8, p. 2394-2399, 2009., Hogendorp et al. 2012HOGENDORP, B. K.; CLOYD, R. A.; SWIADER, J. M. Determination of silicon concentration in some horticultural plants. Hortscience, v. 47, n. 11, p. 1593-1595, 2012., Zanão Júnior et al. 2013ZANÃO JÚNIOR, L. A. et al. Produção de rosas influenciada pela aplicação de doses de silício no substrato. Revista Brasileira de Ciência do Solo, v. 37, n. 6, p. 1611-1619, 2013., Park et al. 2016PARK, Y. G. et al. Silicon and horticultural crops: evaluation of silicon uptake and deposition in floricultural plants. In: TRIPATHI, D. K. et al. (Org.). Silicon in plants: advances and future prospects. Boca Raton: CRC Press, 2016. p. 114-127.). Beneficial effects of supplemental Si have been observed in many of these species, and these effects vary and strongly depend on the species, and even the cultivar (Jana & Jeong 2014JANA, S.; JEONG, B. R. Silicon: the most under-appreciated element in horticultural crops. Trends in Horticultural Research, v. 4, n. 1, p. 1-19, 2014., Park et al. 2016PARK, Y. G. et al. Silicon and horticultural crops: evaluation of silicon uptake and deposition in floricultural plants. In: TRIPATHI, D. K. et al. (Org.). Silicon in plants: advances and future prospects. Boca Raton: CRC Press, 2016. p. 114-127.)

Many substrates for ornamental plants contain very low levels of plant-available Si. Therefore, Si supplementation provides several benefits for the plants, such as those related to structural functions in plant architecture and water stress, from which gladiolus could benefit, since substrates for greenhouse cultivation of this crop often contain little soluble Si.

This study aimed at evaluating the effects of Si on the morphological traits and nutrient concentrations of three gladiolus cultivars ('White Friendship', 'Rose Friendship' and 'Red Beauty') grown in a greenhouse.

MATERIAL AND METHODS

The experiment was conducted from April to August 2014, in a greenhouse located in the western region of the Paraná State, Brazil (24º33'S and 54º31'W). Daily average temperature was 30.2 ºC, with average minimum of 22.3 ºC and maximum of 33.2 ºC.

The experimental design was randomized blocks, in a 3 x 4 factorial scheme, with three gladiolus cultivars ('White Friendship', 'Rose Friendship' and 'Red Beauty') and four Si doses (0 mg dm-3, 150 mg dm-3, 300 mg dm-3 and 600 mg dm-3), with four replications. Each experimental unit consisted of a pot with two plants.

The 'White Friendship' and 'Rose Friendship' cultivars have an early cycle, while 'Red Beauty' has an intermediate cycle. 'Red Beauty' displays red petals, 'White Friendship' white petals, and 'Rose Friendship' pink petals.

Commercial corms (Premium Seeds, Brazil) with a perimeter of 14-16 cm were used. The corms were planted at 7 cm deep, in polyethylene pots containing 12 dm3 of a mixture of Red Oxisol clay + fine washed sand + coconut shell fiber, in the proportion of 1:2:0.5 (v/v/v). The concentration of soluble Si in the substrate was 2 mg dm³, as determined by the colorimetric method, using CaCl2 as an extractor, and according to the methodology described by Korndörfer et al. (2004)KORNDÖRFER, G. H.; PEREIRA, H. S.; NOLA, A. Análise de silício: solo, planta e fertilizante. Uberlândia: GPSi-ICIAG-UFU, 2004.. At mixing, the substrate was amended with 100 mg dm-3 of P2O5, using single superphosphate (18 % of P2O5 and 8 % of S).

Potassium silicate (K2SiO3), containing 120 g kg-1 of Si and 150 g kg-1 of K2O, was used as a source of Si. Untreated plants and plants treated with 150 mg dm-3 and 300 mg dm-3 of Si received KCl to balance K among treatments. Thus, all treatments received 625 mg dm-3 of K. The pH of the application solution was adjusted to 6.0, with HCl 1 mol L-1. Each cultivar received half of the Si dose at 15 days after emergence (DAE) and the other half one week later, via fertigation.

Fertilizer applications were carried out at 10, 17, 21 and 30 DAE, by applying 200 mL of a nutrient solution, which contained the following salts: NH4NO3, CO(NH2)2, MgSO4.7H2O, H3BO3, CuSO4.5H2O, FeSO4.7H2O, MnCl2.4H2O, (NH4)6Mo7O24.4H2O and ZnSO4.7H2O. The following are the total amounts of nutrients applied (mg dm-3): N = 160; S = 60; Mg = 60; B = 1; Cu = 1.5; Fe = 2; Mn = 3.5; Mo = 0.2; and Zn = 5.

Tillers were eliminated during the experiment, and there was no need to control pests and diseases. Plants were irrigated manually in the morning on a daily basis until the yellowing of the leaves, which coincided with the maturation of corms and cormels. The substrate weighing method was used to determine the field capacity of soil in the pots, which was maintained at approximately 80 % (Porto et al. 2014PORTO, R. A. et al. Effects of water replacement levels and nitrogen fertilization on growth and production of gladiolus in a greenhouse. Agricultural Water Management, v. 131, n. 1, p. 50-56, 2014.).

Morphological evaluations were carried out using the phenological scale for gladiolus proposed by Schwab et al. (2015a)SCHWAB, N. T. et al. A phenological scale for the development of gladiolus. Annals of Applied Biology, v. 166, n. 3, p. 496-507, 2015a.. The following traits were evaluated: plant height (cm), number of days until spike harvest, spike length (cm), number of florets per spike, floret diameter (cm), stem diameter (cm), dry mass of leaves and spikes (g plant-1), and leaf nutrient and silicon concentrations.

The plant height, number of days until spike harvest, stem diameter, and leaf nutrient and silicon concentrations were evaluated at the R2 phenological stage, when the first three florets on the spike presented the color of the petals. Plant height was measured from the substrate line to the tip of the spike. The marketable harvest point of the spike was the number of days between corm planting and the R2 stage. Stem diameter at the lowest floret was measured with a digital caliper (two measurements were made per stem).

Nutrient and Si concentrations were determined in the two most mature leaves from each plant. Leaves were collected and washed in distilled water, packed in kraft paper bags and dried in a forced-air oven for 72 h, at 65 ºC, until constant mass. They were then weighed on a semi-analytical scale to determine dry matter and subsequently ground in a Wiley-type mill with a 0.84 mm screen. The material was mineralized by a mixture of nitric and perchloric acids (3:1 v v-1). Concentrations of Ca, Mg, Cu, Fe, Mn and Zn were determined by atomic absorption spectrophotometry; K by flame emission photometry; S by turbidimetry; and P by colorimetry. To determine N concentrations, samples were mineralized with sulfuric acid, according to the semi-micro Kjeldahl method. Concentrations of B were determined by the Azomethine-H colorimetric method, after the incineration of the samples. Concentrations of Si were determined by the alkaline digestion method and dosing by the colorimetric method (Korndörfer et al. 2004KORNDÖRFER, G. H.; PEREIRA, H. S.; NOLA, A. Análise de silício: solo, planta e fertilizante. Uberlândia: GPSi-ICIAG-UFU, 2004.).

The floret diameter of the lowest two florets on the spike was measured with digital calipers at the R3 stage, when the corolla of the first floret at the bottom of the spike is open, with visible anthers. The spike length and number of florets per spike were determined at the R3.6 stage, when half of the florets senesced. Spike length was measured from the lowest floret to the tip of the spike.

At the R6 stage, when all parts of the plant above the ground senesced, the leaves and spike (composed of the stem and florets) were separated and packed into kraft paper bags. The material was then dried in a forced-air oven for 72 h, at 65 ºC, until constant mass. After this period, the material was weighed on a semi-analytical scale, to record the dry matter. The mass of the leaf dry matter obtained at R2 was added to that obtained at R6, to calculate the total leaf dry matter yield.

Data were submitted to analysis of variance, using the statistical software Assistat (Silva & Azevedo 2016SILVA, F. A. S.; AZEVEDO, C. A. V. The Assistat software version 7.7 and its use in the analysis of experimental data. African Journal of Agricultural Research, v. 11, n. 39, p. 3733-3740, 2016.). Averages for the cultivars were compared by the Tukey test at 5 %, and the effect of Si doses by regression analysis. Correlation coefficients were tested at 1 % by the t-test.

RESULTS AND DISCUSSION

As no significant effect of interaction between Si doses and cultivars was observed, the results are discussed separately for each factor.

The plant height, spike length, number and diameter of florets on the spike and leaf and spike dry matter yield were higher for 'White Friendship' and 'Red Beauty' than for 'Rose Friendship' (Table 1).

Table 1
Plant height, days to spike harvest, spike length, florets per spike, floret diameter, stem diameter and leaf and spike dry matter yield of gladiolus cultivars grown in pots.

In gladiolus, plant height corresponds to the length of the stem, and the marketable rates of "average", "long" and "extra" are based on this trait, as well as on stem diameter (Tombolato et al. 2010TOMBOLATO, A. F. C. et al. Bulbosas ornamentais no Brasil. Revista Brasileira de Horticultura Ornamental, v. 16, n. 2, p. 127-138, 2010.). According to this classification, spikes of 'White Friendship' and 'Red Beauty' were rated as "extra", being over 110 cm long, with a minimum stem diameter of 1.0 cm. 'Rose Friendship' produced stems classified as "long", not because of the spike length (above 110 cm), but due to the stem diameter, which was between 1 cm and 0.8 cm.

All three cultivars produced marketable stem and spike length. According to Schwab et al. (2015b)SCHWAB, N. T. et al. Parâmetros quantitativos de hastes florais de gladíolo conforme a data de plantio em ambiente subtropical. Pesquisa Agropecuária Brasileira, v. 50, n. 10, p. 902-911, 2015b., the proportion of the length of the spike to the length of the stem is aesthetically pleasing when above 40 %. 'White Friendship' and 'Red Beauty', with stems classified as "extra" (110 cm) and spike length of 53.09 cm and 52.13 cm, reached proportions of 48 % and 47 %, respectively. In 'Rose Friendship', with stems classified as "long" (90 cm) and spike length of 42.56 cm, this proportion was 47 %.

The number of florets per spike was, on average, 14.1, 12.3 and 13.7, respectively for 'White Friendship', 'Rose Friendship' and 'Red Beauty' (Table 1). According to Paiva et al. (2012)PAIVA, P. D. O.; FERNANDES, K. D.; CERATTI, M. Gladíolo. In: PAIVA, P. D. O; ALMEIDA, E. F. A. (Orgs.). Produção de flores de corte. Lavras: UFLa, 2012. p. 449-469., the number of florets per spike may range from 8 to 18. Porto et al. (2012)PORTO, R. A. et al. Adubação nitrogenada no crescimento e produção de gladíolos em Latossolo Vermelho no Cerrado. Agroecossistemas, v. 4, n. 1, p. 2-11, 2012., studying the fertilization of the 'White Friendship' gladiolus, observed 12 to 14 florets per spike. Ruppenthal & Castro (2005)RUPPENTHAL, V.; CASTRO, A. M. C. Efeito do composto de lixo urbano na nutrição e produção de gladíolos. Revista Brasileira de Ciência do Solo, v. 29, n. 1, p. 145-150, 2005., evaluating the effects of different sources of fertilization (mineral and organic) on 'Red Beauty', found, on average, 15.8 florets per spike.

The number of days to spike harvest was lower for the 'White Friendship' and 'Rose Friendship' than for 'Red Beauty' (Table 1). 'White Friendship' and 'Rose Friendship' had a short cycle of approximately 67 and 63 days, respectively, while 'Red Beauty' had a median cycle of approximately 92 days. According to Paiva et al. (2012)PAIVA, P. D. O.; FERNANDES, K. D.; CERATTI, M. Gladíolo. In: PAIVA, P. D. O; ALMEIDA, E. F. A. (Orgs.). Produção de flores de corte. Lavras: UFLa, 2012. p. 449-469. and Barbosa (2011)BARBOSA, J. G. Palma-de-santa-rita (gladíolo): produção comercial de flores e bulbos. Viçosa: Ed. UFV, 2011., such cycles are typical for these cultivars.

Stem diameter was larger in 'Red Beauty' (1.02 cm) and 'White Friendship' (1.00 cm) than in 'Rose Friendship' (0.88 cm) (Table 1). This variable, whose minimum value should be 0.5 cm, indirectly indicates the strength of the stem. There were no broken stems in this trial.

Floret diameter did not differ among cultivars, being, on average, 9.73 cm (Table 1). Thus, according to the classification proposed by Sheela (2008)SHEELA, V. L. Flowers for trade. New Delhi: New India Publishing Agency, 2008., florets were rated as "decorative", i.e., between 8.9 cm and 11.4 cm in diameter.

The dry matter yield of spikes and stems in 'White Friendship' and 'Red Beauty' were higher than in 'Rose Friendship', since they produced bigger plants with bigger spikes and thicker stems.

In the present study, Si additions to the substrate did not influence any of the morphological traits evaluated (Table 2). However, the Si fertilization of some species, such as gerbera, sunflower, rose, zinnia and phalaenopsis orchid, has been reported to improve the yield and quality of flowers. These species are considered Si accumulators (Kamenidou et al. 2008KAMENIDOU, S.; CAVINS, T. J.; MAREK, S. Silicon supplements affect horticultural traits of greenhouse-produced ornamental sunflowers. Hortscience, v. 43, n. 1, p. 236-239, 2008., 2009KAMENIDOU, S.; CAVINS, T. J.; MAREK, S. Evaluation of silicon as a nutritional supplement for greenhouse zinnia production. Scientia Horticulturae, v. 119, n. 3, p. 297-301, 2009. and 2010KAMENIDOU, S.; CAVINS, T. J.; MAREK, S. Silicon supplements affect floricultural quality traits and elemental nutrient concentrations of greenhouse produced gerbera. Scientia Horticulturae, v. 123, n. 3, p. 390-394, 2010., Vendrame et al. 2010VENDRAME, W. A. et al. Silicon fertilization affects growth of hybrid phalaenopsis orchid liners. Horttechnology, v. 20, n. 3, p. 603-607, 2010., Zanão Júnior et al. 2013ZANÃO JÚNIOR, L. A. et al. Produção de rosas influenciada pela aplicação de doses de silício no substrato. Revista Brasileira de Ciência do Solo, v. 37, n. 6, p. 1611-1619, 2013.).

Table 2
Plant height, days to spike harvest, spike length, florets per spike, floret diameter, stem diameter and leaf and spike dry matter yield, as a function of Si doses applied to the substrate of potted gladiolus.

The response to Si supplementation mainly depends on the amount of Si the plant takes up and the amount of Si that is available in the substrate. Carvalho-Zanão et al. (2012)CARVALHO-ZANÃO, M. P. et al. Yield and shelf life of chrysanthemum in response to the silicon application. Horticultura Brasileira, v. 30, n. 3, p. 403-408, 2012. did not observe any significant response of chrysanthemum to supplemental Si. Mattson & Leatherwood (2010)MATTSON, N. S.; LEATHERWOOD, W. R. Potassium silicate drenches increase leaf silicon content and affect morphological traits of several floriculture crops grown in a peat-based substrate. HortScience, v. 45, n. 1, p. 43-47, 2010., evaluating 21 species of flowers, found that, among these species, begonia, petunia, geranium, impatiens and vinca did not present any significant morphological response to the application of Si. In this study, the low availability of Si in the substrate and the lack of response to Si supplementation show that gladiolus has little sensitivity to Si fertilization.

'White Friendship' and 'Rose Friendship' presented a concentration of leaf N, P, K, Mg, B and Zn higher than 'Red Beauty'. On the other hand, leaf concentrations of Fe and Mn were the highest ones in 'Rose Friendship'. The concentrations of Ca, Cu and S did not differ among the cultivars (Table 3).

Table 3
Nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, boron, copper, iron, manganese, zinc and silicon concentrations in leaves of gladiolus cultivars grown in pots.

Different nutrient demands by cultivars of the same species were observed by Villas Bôas et al. (2008)VILLAS BÔAS, R. L. et al. Exportação de nutrientes e qualidade de cultivares de rosas em campo e em ambiente protegido. Horticultura Brasileira, v. 26, n. 4, p. 515-519, 2008. in rose, by Ludwig et al. (2013)LUDWIG, F. et al. Absorção de nutrientes em cultivares de gérbera cultivada em vaso. Horticultura Brasileira, v. 31, n. 4, p. 622-627, 2013. in gerbera and by Ferreira et al. (2012)FERREIRA, L. D. B. et al. Acúmulo de macronutrientes em cultivares de crisântemo para vaso, em Goianira - GO. Revista Brasileira de Ciências Agrárias, v. 7, n. 1, p. 9-16, 2012. in chrysanthemum. According to Horn et al. (2006)HORN, D. et al. Parâmetros cinéticos e morfológicos da absorção de nutrientes em cultivares de milho com variabilidade genética contrastante. Revista Brasileira de Ciência do Solo, v. 30, n. 1, p. 77-85, 2006. and Rengel & Damon (2008)RENGEL, Z.; DAMON, P. M. Crops and genotypes differ in efficiency of potassium uptake and use. Physiologia Plantarum, v. 133, n. 4, p. 624-636, 2008., this difference is due to genetic characteristics and is caused by the variation in the kinetic parameters of nutrient uptake and morphological differences of the root system.

Average leaf concentrations of N, P, K, Ca, Mg and S (g kg-1) were, respectively, as it follows: 40.72, 3.64, 43.03, 14.38, 4.26 and 3.82 for 'White Friendship'; 41.84, 3.78, 45.29, 15.91, 4.47 and 3.90 for 'Rose Friendship'; 36.64, 3.30, 40.65, 14.62, 3.57 and 3.39 for 'Red Beauty'. Regarding the micronutrients B, Cu, Fe, Mn and Zn, their mean leaf concentrations (mg kg-1) were: 54.31, 10.10, 79.75, 62.87 and 34.06 for 'White Friendship'; 55.93, 10.54, 115.41, 97.97 and 35.52 for 'Rose Friendship'; 52.88, 10.28, 74.56, 58.28 and 31.00 for 'Red Beauty' (Table 3). According to Mills & Jones Júnior (1996)MILLS, H. A.; JONES JÚNIOR, J. B. Plant analysis handbook II: a practical sampling, preparation, analysis and interpretation guide. Athens: MicroMacro, 1996., all nutrient concentrations observed in this study were adequate for gladiolus.

The decreasing order of leaf macronutrient concentrations (g kg-1) in all three cultivars was the same: K > N > Ca > Mg > S > P. Regarding micronutrients, the decreasing order of leaf concentrations (mg kg-1) was also the same: Fe > Mn > B > Zn > Cu. Woltz (1954)WOLTZ, S. S. Studies on the nutritional requirements of gladiolus. Florida Agricultural Experiment Station Journal Series, v. 296, n. 1, p. 330-335, 1954. found that the decreasing order of macronutrients in the 'Elisabeth The Queen' gladiolus was K > N > Ca > P > Mg, while the order of micronutrients was Fe > Mn > Cu. Haag et al. (1970)HAAG, H. P.; OLIVEIRA, G. D.; MATTOS, J. R. Nutrição mineral de plantas ornamentais: I. Absorção de nutrientes pela cultura de gladíolos. Anais da Escola Superior de Agricultura Luiz de Queiroz, v. 27, n. 1, p. 125-141, 1970. found that the 'Itapetininga' gladiolus presented the following order of leaf macronutrients at flowering: K > N > Ca > P > S > Mg. In the case of micronutrients, the order was the same as in the present study. Ruppenthal & Castro (2005)RUPPENTHAL, V.; CASTRO, A. M. C. Efeito do composto de lixo urbano na nutrição e produção de gladíolos. Revista Brasileira de Ciência do Solo, v. 29, n. 1, p. 145-150, 2005., evaluating different effects of organic and chemical fertilization of the 'Red Beauty' gladiolus, found that the decreasing order of leaf nutrient concentrations was K > Ca > Mg > P > Fe > Cu > Zn > Mn.

There were differences of Si uptake among cultivars: 'White Friendship' demonstrated the highest concentration (0.45 g kg-1), followed by 'Rose Friendship' (0.38 g kg-1) and 'Red Beauty' (0.37 g kg-1) (Table 3). Carvalho-Zanão et al. (2012)CARVALHO-ZANÃO, M. P. et al. Yield and shelf life of chrysanthemum in response to the silicon application. Horticultura Brasileira, v. 30, n. 3, p. 403-408, 2012. also observed genotypic differences regarding the uptake of Si in chrysanthemum and Zanão Júnior et al. (2013)ZANÃO JÚNIOR, L. A. et al. Produção de rosas influenciada pela aplicação de doses de silício no substrato. Revista Brasileira de Ciência do Solo, v. 37, n. 6, p. 1611-1619, 2013. in roses. According to Epstein (1999)EPSTEIN, E. Silicon. Annual Review of Plant Physiology and Plant Molecular Biology, v. 50, n. 1, p. 641-664, 1999., Si concentrations in plants generally range 0.1-100 g kg-1 and, in plants known as Si accumulators, such as rice, it may be higher than that of macronutrients (> 100 g kg-1).

According to the classification proposed by Ma et al. (2001)MA, J. F.; MIYAKE, Y.; TAKAHASHI, E. Silicon as a beneficial element for crop plants. In: DATNOFF, L. E.; SNYDER, G. H.; KORNDORFER, G. H. (Eds.). Silicon in agriculture. Dordrecht: Elsevier Science, 2001. p. 17-39., all three cultivars were classified as non-accumulators of Si, as concentrations of this element in leaves were less than 5 g kg-1.

Silicon applications to the substrate did not affect the uptake of any macro or micronutrient, possibly because the cultivars did not absorb large amounts of Si. Changes in nutrient and Al uptake induced by Si applications were observed in Si-accumulating crops, mainly under biotic or abiotic stress conditions. Chen et al. (2000)CHEN, J. et al. Silicon: the estranged medium element. 2000. Available at: <http://www.fngla.org/education-and-research/research/reports/75/finalreport.pdf>. Access on: Jan. 24, 2017.
http://www.fngla.org/education-and-resea...
stated that Si inhibits the uptake of Al, Mn and Na, and facilitates the uptake of P, Mg, K, Fe, Cu and Zn.

In this trial, only leaf Si concentrations grew linearly with Si doses, because Si was added to the nutrient solution in a plant-available form (Table 4). Evaluating 21 ornamental species cultivated in a peat-based substrate and weekly fertilized with 100 mg L-1 of potassium silicate, Mattson & Leatherwood (2010)MATTSON, N. S.; LEATHERWOOD, W. R. Potassium silicate drenches increase leaf silicon content and affect morphological traits of several floriculture crops grown in a peat-based substrate. HortScience, v. 45, n. 1, p. 43-47, 2010. found a 13-145 % increase in the leaf Si concentration in +Si plants, relatively to -Si plants.

Table 4
Nitrogen, phosphorus, potassium, calcium, magnesium, sulfur, boron, copper, iron, manganese, zinc and silicon concentrations in leaves of gladiolus cultivated in pots, as a function of silicon applications to the substrate.

Although the plants absorbed Si linearly with the concentration of this element in the substrate, no effect was verified on the morphology of the plants. Probably, the low Si absorption may justify the lack of significant effect of this element. Even with the application of 600 mg L-1 of Si, the leaves only presented contents of 0.55 g kg-1 of Si. With this low absorption rate and absence of effects on plant morphology, there are no subsidies for the recommendation of Si supplementation in the gladiolus crop. According to Carvalho-Zanão et al. (2012)CARVALHO-ZANÃO, M. P. et al. Yield and shelf life of chrysanthemum in response to the silicon application. Horticultura Brasileira, v. 30, n. 3, p. 403-408, 2012., for the benefits of Si to occur, it is necessary that the plant be an accumulator of this element. By evaluating the application of Si doses in three chrysanthemum cultivars, the authors verified the absorption of Si in small quantities, and that this absorption did not result in any effect on the morphological traits evaluated, including floral longevity.

CONCLUSIONS

  1. The 'White Friendship' and 'Red Beauty' gladiolus cultivars produce taller plants, with longer spikes and thicker and heavier stems, than 'Rose Friendship';

  2. The decreasing order of leaf nutrient concentrations in all three cultivars is the same: K > N > Ca > Mg > S > P > Fe > Mn > B > Zn > Cu;

  3. All cultivars evaluated may be classified as Si non-accumulators;

  4. Silicon additions to the substrate do not affect any morphological variable, or the uptake of N, P, K, Ca, Mg, S, B, Cu, Fe, Mn and Zn, in all the gladiolus cultivars evaluated, suggesting that Si fertilization may not enhance the gladiolus production.

ACKNOWLEDGMENTS

The authors thank the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Capes), for the scholarship granted to the first author.

REFERENCES

  • BARBOSA, J. G. Palma-de-santa-rita (gladíolo): produção comercial de flores e bulbos. Viçosa: Ed. UFV, 2011.
  • CARVALHO, M. P. et al. Silício melhora produção e qualidade do girassol ornamental em vaso. Ciência Rural, v. 39, n. 8, p. 2394-2399, 2009.
  • CARVALHO, P. R. et al. Efeito do silício na qualidade de flores de Dendrobium nobile (Orchidaceae). Semina: Ciências Agrárias, v. 34, n. 4, p. 1615-1622, 2013.
  • CARVALHO-ZANÃO, M. P. et al. Yield and shelf life of chrysanthemum in response to the silicon application. Horticultura Brasileira, v. 30, n. 3, p. 403-408, 2012.
  • CHEN, J. et al. Silicon: the estranged medium element. 2000. Available at: <http://www.fngla.org/education-and-research/research/reports/75/finalreport.pdf>. Access on: Jan. 24, 2017.
    » http://www.fngla.org/education-and-research/research/reports/75/finalreport.pdf
  • CURRIE, H. A.; PERRY, C. C. Silica in plants: biological, biochemical and chemical studies. Annals of Botany, v. 100, n. 7, p. 1383-1389, 2007.
  • EPSTEIN, E.; BLOOM, A. J. Mineral nutrition of plants: principles and perspectives. Sunderland: Sinauer Associates, 2005.
  • EPSTEIN, E. Silicon. Annual Review of Plant Physiology and Plant Molecular Biology, v. 50, n. 1, p. 641-664, 1999.
  • FERREIRA, L. D. B. et al. Acúmulo de macronutrientes em cultivares de crisântemo para vaso, em Goianira - GO. Revista Brasileira de Ciências Agrárias, v. 7, n. 1, p. 9-16, 2012.
  • HAAG, H. P.; OLIVEIRA, G. D.; MATTOS, J. R. Nutrição mineral de plantas ornamentais: I. Absorção de nutrientes pela cultura de gladíolos. Anais da Escola Superior de Agricultura Luiz de Queiroz, v. 27, n. 1, p. 125-141, 1970.
  • HOGENDORP, B. K.; CLOYD, R. A.; SWIADER, J. M. Determination of silicon concentration in some horticultural plants. Hortscience, v. 47, n. 11, p. 1593-1595, 2012.
  • HORN, D. et al. Parâmetros cinéticos e morfológicos da absorção de nutrientes em cultivares de milho com variabilidade genética contrastante. Revista Brasileira de Ciência do Solo, v. 30, n. 1, p. 77-85, 2006.
  • JANA, S.; JEONG, B. R. Silicon: the most under-appreciated element in horticultural crops. Trends in Horticultural Research, v. 4, n. 1, p. 1-19, 2014.
  • KAMENIDOU, S.; CAVINS, T. J.; MAREK, S. Evaluation of silicon as a nutritional supplement for greenhouse zinnia production. Scientia Horticulturae, v. 119, n. 3, p. 297-301, 2009.
  • KAMENIDOU, S.; CAVINS, T. J.; MAREK, S. Silicon supplements affect horticultural traits of greenhouse-produced ornamental sunflowers. Hortscience, v. 43, n. 1, p. 236-239, 2008.
  • KAMENIDOU, S.; CAVINS, T. J.; MAREK, S. Silicon supplements affect floricultural quality traits and elemental nutrient concentrations of greenhouse produced gerbera. Scientia Horticulturae, v. 123, n. 3, p. 390-394, 2010.
  • KORNDÖRFER, G. H.; PEREIRA, H. S.; NOLA, A. Análise de silício: solo, planta e fertilizante. Uberlândia: GPSi-ICIAG-UFU, 2004.
  • LUDWIG, F. et al. Absorção de nutrientes em cultivares de gérbera cultivada em vaso. Horticultura Brasileira, v. 31, n. 4, p. 622-627, 2013.
  • MA, J. F.; MIYAKE, Y.; TAKAHASHI, E. Silicon as a beneficial element for crop plants. In: DATNOFF, L. E.; SNYDER, G. H.; KORNDORFER, G. H. (Eds.). Silicon in agriculture Dordrecht: Elsevier Science, 2001. p. 17-39.
  • MATTSON, N. S.; LEATHERWOOD, W. R. Potassium silicate drenches increase leaf silicon content and affect morphological traits of several floriculture crops grown in a peat-based substrate. HortScience, v. 45, n. 1, p. 43-47, 2010.
  • MILLS, H. A.; JONES JÚNIOR, J. B. Plant analysis handbook II: a practical sampling, preparation, analysis and interpretation guide. Athens: MicroMacro, 1996.
  • PAIVA, P. D. O.; FERNANDES, K. D.; CERATTI, M. Gladíolo. In: PAIVA, P. D. O; ALMEIDA, E. F. A. (Orgs.). Produção de flores de corte Lavras: UFLa, 2012. p. 449-469.
  • PARK, Y. G. et al. Silicon and horticultural crops: evaluation of silicon uptake and deposition in floricultural plants. In: TRIPATHI, D. K. et al. (Org.). Silicon in plants: advances and future prospects. Boca Raton: CRC Press, 2016. p. 114-127.
  • PORTO, R. A. et al. Adubação nitrogenada no crescimento e produção de gladíolos em Latossolo Vermelho no Cerrado. Agroecossistemas, v. 4, n. 1, p. 2-11, 2012.
  • PORTO, R. A. et al. Effects of water replacement levels and nitrogen fertilization on growth and production of gladiolus in a greenhouse. Agricultural Water Management, v. 131, n. 1, p. 50-56, 2014.
  • RENGEL, Z.; DAMON, P. M. Crops and genotypes differ in efficiency of potassium uptake and use. Physiologia Plantarum, v. 133, n. 4, p. 624-636, 2008.
  • RUPPENTHAL, V.; CASTRO, A. M. C. Efeito do composto de lixo urbano na nutrição e produção de gladíolos. Revista Brasileira de Ciência do Solo, v. 29, n. 1, p. 145-150, 2005.
  • SCHWAB, N. T. et al. A phenological scale for the development of gladiolus. Annals of Applied Biology, v. 166, n. 3, p. 496-507, 2015a.
  • SCHWAB, N. T. et al. Parâmetros quantitativos de hastes florais de gladíolo conforme a data de plantio em ambiente subtropical. Pesquisa Agropecuária Brasileira, v. 50, n. 10, p. 902-911, 2015b.
  • SHEELA, V. L. Flowers for trade New Delhi: New India Publishing Agency, 2008.
  • SILVA, F. A. S.; AZEVEDO, C. A. V. The Assistat software version 7.7 and its use in the analysis of experimental data. African Journal of Agricultural Research, v. 11, n. 39, p. 3733-3740, 2016.
  • TAIZ, L.; ZEIGER, E. Fisiologia vegetal 5. ed. Porto Alegre: Artmed, 2013.
  • TOMBOLATO, A. F. C. et al. Bulbosas ornamentais no Brasil. Revista Brasileira de Horticultura Ornamental, v. 16, n. 2, p. 127-138, 2010.
  • VENDRAME, W. A. et al. Silicon fertilization affects growth of hybrid phalaenopsis orchid liners. Horttechnology, v. 20, n. 3, p. 603-607, 2010.
  • VILLAS BÔAS, R. L. et al. Exportação de nutrientes e qualidade de cultivares de rosas em campo e em ambiente protegido. Horticultura Brasileira, v. 26, n. 4, p. 515-519, 2008.
  • WOLTZ, S. S. Studies on the nutritional requirements of gladiolus. Florida Agricultural Experiment Station Journal Series, v. 296, n. 1, p. 330-335, 1954.
  • ZANÃO JÚNIOR, L. A. et al. Produção de rosas influenciada pela aplicação de doses de silício no substrato. Revista Brasileira de Ciência do Solo, v. 37, n. 6, p. 1611-1619, 2013.

Publication Dates

  • Publication in this collection
    Apr-Jun 2017

History

  • Received
    Dec 2016
  • Accepted
    June 2017
Escola de Agronomia/UFG Caixa Postal 131 - Campus II, 74001-970 Goiânia-GO / Brasil, 55 62 3521-1552 - Goiânia - GO - Brazil
E-mail: revistapat.agro@ufg.br