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Crop Breeding and Applied Biotechnology

versão impressa ISSN 1518-7853versão On-line ISSN 1984-7033

Crop Breed. Appl. Biotechnol. vol.17 no.1 Viçosa jan./mar. 2017

https://doi.org/10.1590/1984-70332017v17n1a3 

ARTICLE

Morphological and physiological characteristics in vitro anthurium plantlets exposed to silicon

Gabrielen de Maria Gomes Dias1  * 

Joyce Dória Rodrigues Soares2 

Suelen Francisca Ribeiro3 

Adalvan Daniel Martins2 

Moacir Pasqual2 

Eduardo Alves4 

1 Universidade da Integração da Lusofonia Afro-Brasileira (UNILAB), Instituto de Desenvolvimento Rural, Avenida da Abolição, 3, 62.790-000, Redenção, CE, Brazil.

2 Universidade Federal de Lavras (UFLA), Departamento de Agricultura, CP 3037, 37.200-000, Lavras, MG, Brazil

3 UFLA, Departamento de Biologia, Brazil

4 UFLA, Departamento de Fitopatologia, Brazil


Abstract

The objective was to evaluate morphological and physiological differences in anthurium plants in vitro, with the use of silicon added to the culture medium. Nodal segments were inoculated in Pierik with different sodium silicate concentrations (0.0, 0.5, 1.0 or 2.0 mg L-1). After 100 days in a growth room, phytotechnical characteristics were evaluated, physiological concentrations of silicon, photosynthetic pigments and microanalysis X-ray. A higher yield of chlorophyll a and b, was observed in plants supplemented with 2.0 mg L-1 of sodium silicate. Anthurium plants showed better growth development with an increase in the number of leaves, dry weight and length of the aereal part in plants supplemented with 0.5 and 2.0 mg L-1 sodium silicate. It was also observed an increase in the number of roots of plants supplemented with 1.0 mg L-1 of sodium silicate. The use of sodium silicate in culture medium improves the quality of plantlets with an increased absorption of nutrients in the plant Anthurium.

Key words: Anthurium andraeanum; growth; development; sodium silicate.

INTRODUCTION

Anthurium is currently considered to be a product of great business potential in domestic and foreign floriculture markets. Anthurium is prized not only for its natural beauty and the color structure of its flowers, but also for its high durability topost-harvest (Junqueira and Peetz 2012).

Several studies have been conducted using Anthurium tissue culture to evaluate the potential of obtaining plantlets using this method. In general, the most important factor has been the cultivar specificity, resulting in the need to develop micropropagation protocols unique to each genotype (Gantait and Mandal 2010).

Puchoa (2005) observed that, in general, researchers working with tissue culture have found a wide variation in the responses obtained in vitro when using different genotypes of anthurium. Consequently, adjustments in the culture medium are essential for obtaining vigorous plants of commercial quality.

The mineral elements that stimulate the growth of plants and that are essential for only a few plant species or under specific conditions are considered beneficial elements (Furlani 2004). These elements are important for the normal growth and development of some plants, but their absence is not considered a limiting factor. One of the elements considered to be beneficial is silicon (Korndörfer 2006).

Although silicon is not considered to be an essential element, the benefits of using this element in agriculture are being increasingly recognized by researchers worldwide. For example, the use of silicates in agriculture, in addition to direct effects on productivity, can a significant contribute in the enhancement and, consequently, reduce the use of pesticides (Reis et al. 2008). The structural role of silicon (Si) in the cell wall can increase the concentrations of hemicellulose and lignin, increasing the rigidity of the cell (Camargo et al. 2007).

Studies on the effects of silicon applied to the in vitro cultivation of floriculture segments are still quite limited. The most recent studies examining the role of Si have been performed in flowers with post-harvest and production, such as calla (Almeida et al. 2009), rose (Locarno et al. 2011), gerbera (Guerrero et al. 2012), chrysanthemum (Carvalho-Zanao et al. 2012, Sivanesan et al. 2013) and ornamental sunflower (Carvalho et al. 2009, Oliveira et al. 2013). The only work examining the role of Si in ornamental plants grown in vitro has been performed in orchids (Soares et al. 2011, Soares et al. 2012). Despite the wide variety of ornamental plants grown commercially, relatively few species have been evaluated for their potential for silicon absorption (Frantz et al. 2010).

Considering the benefits observed for other species, the effect of silicon on the development of plants grown in vitro needs to be assessed, particularly for species with commercial importance, such as anthurium. The present study aimed to evaluate the use of silicon on the growth of Anthurium andraeanum cv. Rubi plants in vitro and to evaluate the morphological and physiological characteristics of the leaves when using concentrations of sodium silicate.

MATERIAL AND METHODS

Nodal segments of Anthurium andraeanum cv. Rubi plantlets established in vitro were inoculated in Pierik solution (Pierik 1976) supplemented with 30 g L-1 sucrose and solidified with 1.8 g L-1 PhytagelTM. Sodium silicate (Na2SiO3) was added to the culture medium at the following concentrations: 0.0, 0.5, 1.0 and 2.0 mg L-1. The pH of the culture medium was adjusted to 5.8, and the culture medium was then autoclaved at 121 °C and 1.2 atm for 20 minutes.

Subsequently, in a laminar flow hood, nodal segments were inoculated in 400 mL flasks containing 50 mL of culture medium and the different sodium silicate concentrations. The vials were maintained in a growth chamber with a photoperiod of 16 hours at 25 ± 2 °C temperature, with a light intensity of 52.5 µmol m-2 s-1. After 100 days, we evaluated the parameters described below:

Phytotechnical features - evaluated all experimental plantlets by observing the number of leaves, the number of roots, the length of the aereal part (cm), the fresh and dry weights of the shoots (g), the root length (cm) and the fresh and dry weights of the roots (g). The dry weight of the plant material was evaluated after drying in an oven at 60 (C temperature for 72 hours or until a constant weight was obtained.

Chlorophyll contents - The contents of chlorophyll a, b and the total chlorophyll contents were quantified according to the method described by Arnon (1949). For this purpose, leaves were collected from 10 plants per treatment, and 0.1 g of leaf tissue was macerated in liquid nitrogen and placed in 80% acetone. The material was then centrifuged at 8,000x g for 15 minutes, the supernatant was collected and diluted to 25 ml, and the absorbance was measured in a spectrophotometer at 663 nm and 645 nm. The pigment content was calculated as described by Lichtenthaler (1987).

Silicon concentration - leaves were collected from 12 plants, dried in a forced-circulation oven at 60 °C temperature to a constant weight and ground separately. The determination of silicon by the molybdenum-blue colorimetric method was performed according to the methodology proposed by Gallo and Furlani (1978).

X-ray microanalysis - samples from the middle third of the second sheet of three plants were fixed in Karnovsky solution (Karnovsky 1965), dehydrated in increasing concentrations of acetone (30%, 50 %, 70 %, 90% and 100%) and then subjected to critical point drying, using liquid CO2 as a transition medium (Robards 1978). The samples were subsequently coated with carbon and analyzed using a Baltec CED 020 LEO-EVO 40 scanning electron microscope, following the protocol described by Alves and Perina (2012).

Experimental design and statistical analyses - The experimental design was completely randomized, with four treatments consisting of 15 vials that each contained 2 explants. The data were subjected to analyses of variance and to regression analyses, with p < 0.05, using the software SISVAR (Ferreira 2011).

RESULTS AND DISCUSSION

The concentrations of sodium silicate applied to the Pierik culture medium affected anthurium seedling growth in vitro. As demonstrated in Figure 1, there was a significant effect of the sodium silicate concentration on the number of leaves, the length of the aereal part, the number of roots and the dry weight of the shoots. Increasing concentrations of sodium silicate appeared to behave quadratically, with the peak of the function indicating the increased production of sheets up to the estimated concentration of 0.7 mg L-1 and further increases in the concentration of sodium silicate resulting in a marked decrease in the number of leaves. Similar results were also observed by Braga et al. (2009) working with strawberry in vitro. However, unlike the results of the present study, Pasqual et al. (2011), working with orchids in vitro, found a greater number of sheets with the use of calcium silicate. Moreover, Asmar et al. (2011), working with in vitro banana, and Oliveira et al. (2013), working with ornamental sunflower, found no differences in the number of leaves when applying sodium silicate and calcium.

Figure 1 Phytotechnical features in Anthurium andraeanum cv. Rubi plantlets after 100 days in culture with different concentrations of sodium silicate. 

With increasing concentrations of sodium silicate, a linear increase in the length of the aerial part of anthurium was observed, with plants treated with the concentration of 2.0 mg L-1 achieving the maximum length of 1.82 cm (Figure 1). For Asmar et al. (2011), the use of sodium silicate provided the largest shoot growth for in vitro banana. Pasqual et al. (2011) obtained higher length of the aereal part for in vitro orchids using 2.0 mg L-1 calcium silicate.

The dry mass of the aerial part of the plant demonstrated a quadratic increase according to increase in the concentration of sodium silicate. The maximum yield was estimated at the concentration of 1.4 mg L-1 sodium silicate (Figure 1). Similarly, Almeida et al. (2009) and Sivanesan et al. (2013) reported that different concentrations of silicon promoted increased dry matter in the aerial parts of the chrysanthemum and chrysanthemum plants. Asmar et al. (2011), working with in vitro banana, reported higher shoot dries mass when using sodium silicate in the culture medium.

A larger number of roots were observed in plants supplemented with 1.0 mg L-1 sodium silicate, with a quadratic response observed for this concentration, followed by a sharp decline in root numbers for plants treated with higher concentrations of sodium silicate (Figure 1). Similar results were observed by Soares et al. (2008) when they worked with sodium silicate in the acclimatization of orchids.

The decrease in the number of roots observed in plants cultivated in higher concentrations of sodium silicate may stem from the fact that any nutrient taken in excess can cause a nutritional imbalance in the plant, including silicon. In studies of mineral nutrition, it is necessary to consider the nutrients as a whole because, in the process of absorption, one nutrient can exert influence over other nutrients, given the possible interactions that may occur (Malavolta et al. 1997).

It can be observed in Figure 2 that there is an increasing trend in the levels of chlorophyll a and b and total chlorophyll levels with increasing concentrations of sodium silicate, and the best result was obtained with 2.0 mg L-1 sodium silicate. The highest levels of chlorophyll b were observed in the control, which was culture medium without the addition of silicon, followed by decreasing levels with increasing concentrations of sodium silicate.

Figure 2 Chlorophyll a and b contents, total chlorophyll and a/b ratio in the leaves of Anthurium andraeanum cv. Rubi plantlets grown for 100 days in vitro in a culture medium containing sodium silicate. 

The results of the present study demonstrated the effectiveness of using silicon on the chlorophyll content of anthurium, similar to the data reported by Gong et al. (2005), Sousa et al. (2010), Locarno et al. (2011) and Sivanesan et al. (2013). These results are likely due to silicon being associated with the maintenance of photosynthesis, the chlorophyll distribution and the protection and preservation of the structural and functional deterioration of cell membranes (Agarie et al. 1998). Increased chlorophyll content with silicon supplementation was also observed by Al-Aghabary et al. (2005) in tomato plants.

The silicon content in the leaves of anthurium was significantly influenced by the concentrations of sodium silicate used. As shown in Figure 3, there was a proportional increase in the concentration silicon in the leaves of anthurium plantlets at higher concentrations of sodium silicate. The highest concentration was estimated to occur at 1.5 mg L-1 sodium silicate, with a quadratic response to increasing concentrations.

Figure 3 Silicon concentrations in shoots of Anthurium andraeanum cv. Rubi cultured in vitro for 100 days. 

In general, plants are considered to be silicon accumulating plants if they have foliar silicon levels greater than 1% and are considered to be non-accumulating plants if they have foliar silicon levels lower than 0.5 % (Ma et al. 2001). Although anthurium are monocotyledonous plants, they are classified as non-accumulative for silicon (0.23 to 0.40%) (Figure 3). Similar results were also observed by Almeida et al. (2009) when working with silicon in the mineral nutrition of calla. Thus, anthurium plantlets have no ability to accumulate silicon in shoots at high concentrations but can benefit from this element even in small quantities.

The presence of silicon in the control can be explained by the fact that silicon is an abundant element in nature that is present everywhere, even on water and its amount varies according to the region (Luz et al. 2006, Larezzini and Bonotto 2014). Si identified in the treatments without sodium silicate likely originated from the water used during the experiment that, although deionized, contained some neutral forms of Si that could not be completely eliminated. However, it is noteworthy that Si was absorbed in insignificant amounts in the control when compared to treatments receiving sodium silicate.

In the X-ray microanalysis (MAX), Si was found on the abaxial side of leaves treated with sodium silicate. Detection of Si was observed in all treatments, including the control. The data confirm the chemical analysis of the leaves, which also identified the presence of silicon in all treatments.

When mapping was performed for silicon (Si), there was an evolutionary distribution related to the concentration of sodium silicate applied to the culture medium (Figures 4B, C and D). The presence of Si in the control was also detected during mapping of the abaxial side of the leaf (Figure 4A).

Figure 4 Mapping of Si on the abaxial epidermis of leaves from Anthurium andraeanum cv. Rubi plantlets cultured in vitro for 100 days, demonstrating the presence and the evolution of the distribution of silicon with increasing concentrations of sodium silicate in the culture medium. a) Control, b) 0.5 mg L- 1, c) 1.0 mg L- 1, d) 2.0 mg L- 1. Bar = 20 μm. 

The polymerization of silicon on the lower surface of the sheet, termed the silicification process, is common in grasses (Lux et al. 2002) and may occur as observed in the dicotyledonous coffee (Pozza et al. 2004). Previously, there have been no reports in the literature regarding the deposition of Si in anthurium. The MAX demonstrated that Si is positioned primarily in the epidermis because, when observed in cross-section, the Si levels in the sheet appeared much lower than in the control.

CONCLUSIONS

Levels of photosynthetic pigments were higher when plants of Anthurium andraeanum cv. Rubi were grown in culture medium supplemented with 2.0 mg L-1 of sodium silicate.

The use of sodium silicate in culture medium improves the quality of plantlets with an increased absorption of nutrients in the plant Anthurium andraeanum cv. Rubi.

ACKNOWLEDGEMENTS

We thank the Coordination of Improvement of Higher Education Personnel (CAPES) for funding, and the National Council for Scientific and Technological Development (CNPq) for granting the scholarship.

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Received: October 06, 2015; Accepted: August 15, 2016

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