Influence of test tube sealing on the morpho-anatomy and ultrastructure of leaves of <i>Aechmea bromeliifolia</i> (Bromeliaceae) grown <i>in vitro</i>

Silva, Elienai Candida e; Sibov, Sérgio Tadeu; Santos, Fernanda Cristina Alcantara dos; Gonçalves, Letícia Almeida

doi:10.1590/2175-7860202071001

Abstract

In vitro grown plants may have abnormal structural and physiological features. However, the type of the sealing material used in tissue culture may minimize such abnormalities. This study evaluates the influence of the type of sealing of test tubes on the anatomical and ultrastructural features of leaves of Aechemea bromeliifolia (Rudge) Baker (Bromeliaceae), an ornamental bromeliad native to Brazil, grown in vitro. Three types of sealing were used: rigid polypropylene cap (PC), polyvinyl chloride film (PVC), and PC coupled with a microporous membrane (PM). Seedlings germinated in a greenhouse were also studied for comparison. Plants grown in test tubes sealed with PM were more similar to those from the greenhouse, as far as the pattern of stomatal opening, the presence of starch grains, and the organization of the internal membrane system of the chloroplasts is concerned. Plants cultivated in test tubes sealed with PC had higher stomatal density and the chloroplasts had large areas without thylakoids in the stroma. Plants grown in test tubes sealed with PVC had few or no starch grains. These results suggest that microporous membrane used coupled with PC sealing provided natural ventilation, thus contributing to a better plant development.

Key words:
chloroplast ultrastructure; in vitro environment; plant tissue culture

Resumo

Plantas desenvolvidas in vitro podem apresentar características estruturais e fisiológicas pouco funcionais. Contudo, o tipo de vedação dos recipientes utilizados na cultura de tecidos pode minimizar tais características. Este estudo avaliou a influência do tipo de vedação dos tubos de ensaio sobre a anatomia e a ultraestrutura das folhas de Aechmea bromeliifolia (Rudge) Baker (Bromeliaceae), uma bromélia ornamental nativa do Brasil, desenvolvidas in vitro. Foram utilizados três tipos de vedação: tampa rígida de polipropileno (PC), filme de policloreto de vinila (PVC) e PC coberta com uma membrana microporosa (PM). Para efeitos de comparação, plantas provenientes de sementes germinadas em telado também foram estudadas. As plantas desenvolvidas em tubos vedados com PM se assemelharam mais às desenvolvidas em telado, quanto à abertura dos estômatos, a presença de grãos de amido e a organização do sistema interno de membranas dos cloroplastos. Nas plantas cultivadas em tubos vedados com PC, houve maior densidade estomática e os cloroplastos ficaram com grandes áreas sem tilacóides no estroma. Na condição PVC, pouco ou nenhum grão de amido foi encontrado. Esses resultados sugerem que a membrana microporosa, adicionada ao orifício da PC, proporcionou uma vedação com ventilação natural, contribuindo para o melhor desenvolvimento das plantas.

Palavras-chave:
ambiente in vitro; cultura de tecidos vegetais; ultraestrutura dos cloroplastos

Introduction

In vitro culture techniques are widely used for the propagation of many plant species, resulting in rapid multiplication and pathogen-free plants that are genetically identical to the original ones (Chen 2004Chen C (2004) Humidity in plant tissue culture vessels. Biosystems Engineering 88: 231-241.). The in vitro environment is characterized by dim light, high relative humidity, low CO₂concentration during the photoperiod, high ethylene concentration, and restricted air movement inside the culture vessel (Kozai & Smith 1995Kozai T & Smith MAL (1995) Environmental control in plant tissue culture - general introduction and overview. In: Aitken-Christie J, Kozai T & Smith MAL (eds.) Automation and environmental control in plant tissue culture, 301-318. Kluwer Academic Publishers, Dordrecht. 574p.). Such features affect the anatomy and physiology of in vitro grown plants, resulting in absent or reduced cuticle, dysfunctional stomata, and poorly developed photosynthetic apparatus. As a consequence, in vitro grown plants may be vulnerable when exposed to the ex vitro environment (Hazarika 2006Hazarika BN (2006) Morpho-phisiological disorders in in vitro culture of plants. Scientia Horticulturae 108: 105-120.).

Some materials used for sealing, such as screw caps, aluminum foils, transparent films (e.g., Parafilm^®), and polypropylene caps, may restrict gas exchange between the culture vessel and the outer atmosphere (Zobayed et al. 2000Zobayed SMA , Afreen F , Kubota C & Kozai T (2000) Evolution of culture vessel for micropropagation: from test tube to culture room. In: Kubota C & Chun C (eds.) Transplant production in the 21st century. Kluwer Academic Publishers, Dordrecht. Pp. 231-237.; Zobayed 2008Zobayed SMA (2008) Aeration in plant tissue culture: Engineering aspects of vessel design. In: Gupta SD & Ibaraki Y (eds.) Plant tissue culture engineering, 313-327. Springer, Dordrecht. 480p.). The sealing material used for in vitro culture has significant influence on plant morpho-anatomy, thus affecting its growth (Gonçalves et al. 2008Gonçalves LA, Geraldine RM, Picoli EAT, Vendrame WA, Carvalho CR & Otoni WC (2008) In vitro propagation of Herreria salsaparilha Martius (Herreriaceae) as affected by different sealing materials and gaseous exchanges. Plant Cell Tissue Organ Culture 92: 243-250. ; Ribeiro et al. 2009Ribeiro APO, Picoli EAT , Lani ERG, Vendrame WA & Otoni WC (2009) The influence of flask sealing on in vitro morphogenesis of eggplant (Solanum melongena L.). In vitro Cellular Developmental Biology - Plant 45: 421-428.). Nonetheless, only a few studies Majada et al. (2002)Majada JP, Fal MA, Tadeo F & Sánchez-Tamés R (2002) Effects of natural ventilation on leaf ultrastructure of Dianthus caryophyllus L. cultured in vitro. In vitro Cellular & Developmental Biology - Plant 38: 272-278., Lucchesini et al. (2006)Lucchesini M, Monteforti G, Mensuali-Sodi A & Serra G (2006) Leaf ultrastructure, photosynthetic rate and growth of myrtle plantlets under different in vitro culture conditions. Biologia Plantarum 50: 161-168. and Sáez et al. (2012a)Sáez PL, Bravo LA, Latsague MI, Sánchez ME & Ríos DG (2012a) Increased light intensity during in vitro culture improves water loss control and photosynthetic performance of Castanea sativa grown in ventilated vessels. Science Horticulturae 138: 7-16. have evaluated the effect of the different types of sealingby using ventilated and non-ventilated vessels, on the ultrastructure of plants grown in vitro.

It is a common practice for culture vessels be kept completely sealed to avoid contamination by microorganisms (Kozai & Kubota 2005Kozai T & Kubota C (2005) In vitro aerial environments and their effects on growth and development of plants. In: Kozai T , Afreen F & Zobayed SMA (eds.) Photoautotrophic (sugar-free medium) micropropagation as a new micropropagation and transplant production system, 31-52. Springer, Dordrecht. 316p.; Kozai 2010Kozai T (2010) Photoautotrophic micropropagation - environmental control for promoting photosynthesis. Propagation of Ornamental Plants 10: 188-204. ). However, in order to enhance gas exchange and to promote normal plant growth, the vessels must be ventilated (Zobayed et al. 2000Zobayed SMA , Afreen F , Kubota C & Kozai T (2000) Evolution of culture vessel for micropropagation: from test tube to culture room. In: Kubota C & Chun C (eds.) Transplant production in the 21st century. Kluwer Academic Publishers, Dordrecht. Pp. 231-237.). Sealing materials that are more permeable can reduce the relative humidity inside the culture vessel, enabling an increased transpiration, and a higher uptake of water and nutrients by the plants (Xiao et al. 2011Xiao Y, Niu G & Kozai T (2011) Development and application of photoautotrophic micropropagation plant system. Plant Cell, Tissue and Organ Culture 105: 149-158.).

Given that the in vitro culture conditions are closely related to plant growth and that the sealing material may improve plant development therefore facilitating the acclimatization phase, herein we evaluate the effect of the type of test tube sealing on the morpho-anatomy and ultrastructure of leaves of Aechmea bromeliifolia (Rudge) Baker (Bromeliaceae) seedlings. A. bromeliifolia is a bromeliad native to Brazil with a huge ornamental potential, which is distributed in Central America, Northwest of South America and from North to South of Brazil. (Luiz-Santos & Wanderley 2012Luiz-Santos A & Wanderley MG (2012) Flora da Serra do Cipó, Minas Gerais: Bromeliaceae - Bromelioideae. Boletim de Botânica da Universidade de São Paulo 30: 89-107.). The in vitro propagation of this species has currently been investigated by the Plant Tissue Culture Laboratory of the Federal University of Goiás (UFG) aiming at avoiding the exploitation of natural populations from the state of Goiás, Brazil. Therefore, in the present study, we compared the growth of plants obtained from seeds using three types of test tube seal with that of plants grown from seeds in a greenhouse.

Material and Methods

Plant material and cultivation conditions

Seeds of A. bromeliifolia were collected from an individual plant from the Bromeliads Collection of the Empresa de Assistência Técnica, Extensão Rural e Pesquisa Agropecuária do estado de Goiás (EMATER-GO), Brazil. The examined material was deposited in the herbarium of the Federal University of Goiás: BRAZIL. GOIÁS: Mossâmedes, Reserva Ecológica Professor José Ângelo Rizzo, 25.IV.2009, T.H.S. Sampaio and A.M. Teles 05 (UFG).

In vitro culture was initiated by placing the seeds in test tubes containing 20 mL half strength basal MS medium (Murashige & Skoog 1962Murashige T & Skoog F (1962) A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia Plantarum 15: 473-497. ) supplemented with 30 g L^-1 sucrose, pH 5.7 ± 0.1, and solidified with 7.0 g L^-1 agar. The total volume of the test tubes was 55 mL. The plants were kept in a growth room at 25 ± 1 ºC with a photoperiod of 16 h, and photosynthetic photon flux density (PPFD) of 43.23 µmol m^-2 s^-1 provided by two cool-white fluorescent lamps. Plants grown in vitro were approximately 9 weeks old when collected for the analyses.

For greenhouse cultivation, seeds (n = 40) were sown in polyethylene terephthalate (PET) bottles as described by Paula & Silva (2004)Paula CC & Silva HMP (2004) Cultivo prático de bromélias. 3ª ed. Universidade Federal de Viçosa, Viçosa. 106p. . The substrate consisted of a mixture of sand and soil (2:1) which was covered with Plantmax^® (Aitkens, Glasgow, UK). The PPFD inside the greenhouse was of 350 µmol m^-2 s^-1 obtained from natural light and water was provided manually whenever needed. Plants grown ex vitro were approximately 10 weeks old when collected for the analyses and were about 1-2.5 cm high (aerial part).

Sealing of test tubes

The test tubes used for in vitro culture were sealed with three types of lids: rigid polypropylene cap (PC), single-layered polyvinyl chloride film (PVC), and PC with 5 mm-diameter holes covered with a membrane composed of two layers of microporous tape (Cremer^®, São Paulo, SP, Brazil) and a single layer of polytetrafluoroethylene film (Amanco^®, Grupo Mexichem, São Paulo, SP, Brazil) (PM) (Saldanha et al. 2012Saldanha CW, Otoni CG, Azevedo JLF, Dias LLC, Rêgo MM & Otoni WC (2012) A low-cost alternative membrane system that promotes growth in nodal cultures of Brazilian ginseng [Pfaffia glomerata (Spreng.) Pedersen]. Plant Cell, Tissue and Organ Culture 110: 413-422.). The PPFD was measured inside the test tubes at the height of 6 cm, resulting in 42.34, 42.32, and 41.09 µmol m^-2 s^-1 for the tubes sealed with PC, PVC, and PM, respectively. We used one seed per tube and 40 test tubes per treatment.

Morpho-anatomical and ultrastructural characterization

For anatomical analyses, the plants were collected at 8 am and the leaves were fixed in FAA (formaldehyde, acetic acid, and 50% ethanol; 1:1:18, by volume) for 48 h (Johansen 1940Johansen DA (1940) Plant microtechnique. McGraw-Hill Book Company, New York and London. 523p.) and stored in 70% ethanol. The middle regions of the most expanded leaves were used for all the analyses. Leaf samples were dehydrated in an ethanolic series (Johansen 1940) and embedded in Leica^® historesin (Leica Microsystems Nußloch GmbH, Heidelberg, Germany) following manufacturer’s recommendations. Cross-sections (12-µm thick) of the samples were obtained using a rotary microtome and stained with toluidine blue (O’Brien et al. 1964O’Brien TP, Feder N & McCully ME (1964) Polychromatic staining of plant cell walls by toluidine blue O. Protoplasma 59: 368-373.), followed by a double stained with 0.1% basic fuchsin and 0.3% astra blue (1:3) (Kraus et al. 1998Kraus JE, Sousa HC, Rezende MH, Castro NM, Vecchi C & Luque R (1998) Astra blue and basic fuchsin double staining of plant material. Biotechnic Histochemistry 73: 235-243. ). Analysis of the surface view of the epidermis was performed using leaf samples that were cleared with a 10% sodium hydroxide solution for 30 min and then were immersed in 10% commercial sodium hypochlorite (2-2.5% active chlorine) until they were completely cleared and stained with 1% aqueous safranin solution (Johansen 1940). To confirm the presence of cuticle, Sudan III (Johansen 1940) was used in freehand cuts of fresh leaf samples.

The scanning electron microscope analysis and photography of fresh leaf samples were carried out using a JSM IT300LV scanning electron microscope (JEOL USA, Inc., Peabody, MA, United States) at the Centro Regional para o Desenvolvimento Tecnológico e Inovação, UFG.

For ultrastructural analysis, leaf fragments (1.0 mm²) were fixed for 24 h in 2.5% glutaraldehyde diluted in 0.1 M sodium cacodylate buffer, pH 7.2, containing picric acid. Samples were washed in cacodylate buffer, post-fixed in 1% osmium tetroxide in the cacodylate buffer for 2 h. Subsequently, leaf fragments were dehydrated in acetone series and embedded in Epon resin EMbed-812 (Electron Microscopy Sciences, Industry Road, Hatfield, PA, United States) (Cotta-Pereira et al. 1976Cotta-Pereira G, Rodrigo FG & David-Ferreira JF (1976) The use of tannic acid-glutaraldehyde in the study of elastic-related fibers. Stain Technology 51: 7-11.). Ultra-thin transverse sections were stained with 2% uranyl acetate solution (20 min), washed in distilled water, immersed in 2% lead citrate solution (6 min), and washed in double distilled water. Samples were analyzed using a JEM 2100 transmission electron microscope (JEOL USA, Inc., Peabody, MA, United States), equipped with an Energy Dispersive X-ray Spectrometer (EDS) (Thermo Fisher Scientific Inc., Waltham, MA, United States). The area of the chloroplasts was measured using the ImageJ software (National Institute of Health, Bethesda, MD, United States). For this analysis, the samples of all treatments were collected at the same time of the day (2 pm).

The anatomical analyses were carried out using five repetitions for each treatment. For cuticle and ultrastructural analysis, three repetitions of each treatment were used. The stomata index (SI) was calculated according to the formula of Salisbury (1927)Salisbury EJ (1927) On the causes and ecological significance of stomatal frequency, with special reference to the woodland flora. Philosophical Transactions of the Royal Society B 216: 1-65., SI (%) = [S/(S+E)] × 100, where S is the number of stomata per unit area and E the number of epidermal cells at the same unit area, these two parameters were counted in 10 field of 0.25-mm² per leaf.

For the height of the aerial part and number of leaves, 12 plants of each treatment were used.

Statistical analysis

The experimental design was completely randomized, and the data were submitted to analysis of variance (ANOVA) by using STATISTICA version 7.0 (StatSoft Inc., Tulsa, OK, United States), where significant main effects were obtained and compared by performing the Tukey’s test (α = 0.05).

Results

The in vitro grown plants had longer aerial parts and a larger number of leaves compared to those cultivated in the greenhouse (Tab. 1). However, the leaves of plants cultivated in vitro were membranaceous, whereas the leaves of those grown in the greenhouse became thicker and rigid. Plants grown in tubes sealed with PC and PM showed similar heights (Tab. 1).

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Table 1
Leaf parameters of A. bromeliifolia grown in greenhouse or under in vitro conditions using three different test tube seals (PC = rigid polypropylene cap; PVC = polyvinyl chloride film; PM = PC covered with a microporous membrane).

The same basic anatomical structure was found in all analyzed leaves: multicellular and uniseriate glandular trichomes (Fig. 1a) at the margin of the leaf (Fig. 1b), one-layered epidermis with thin cuticle; tetracytic stomata found on the abaxial surface and on the margins of the adaxial surface (Fig. 1b) at the same level of other epidermal cells; heterogeneous mesophyll with aquifer parenchyma and chlorenchyma (Fig. 2a,b); collateral vascular bundles with fiber poles associated with the xylem and phloem (Fig. 2c-f). However, some differences were noticed on the aperture of stomata ostioles. Plants developed in the greenhouse had completely closed stomata (Fig. 2g), while plants grown in vitro had either open stomata in tubes sealed with PC and PVC (Fig. 2h,i), and completely closed in tubes sealed with PM sometimes with very reduced aperture (Fig. 2j).

Figure 1
a-b. Scanning electron micrographs of the adaxial leaf surface of A. bromeliifolia grown in test tubes sealed with rigid polypropylene cap covered with microporous membrane – a. detail of a multicellular uniseriate glandular trichome; b. glandular trichomes on the leaf margin and stomata restricted to the leaf margin (arrow). Scale bars: a = 20 nm; b = 100 nm.

Figure 2
a-j. Light microscopy of the cross-sections (a-f) and abaxial surface (g-j) of the middle region (a,b,g-j) and margin (c-f) of A. bromeliifolia leaves – a,c,g. leaves of plants developed in greenhouse; b,d,h. leaves of plants grown in test tubes sealed with rigid polypropylene cap; e,i. leaves of plants developed in test tubes sealed with polyvinyl chloride film; f,j. leaves developed in test tubes sealed with rigid polypropylene cap covered with a microporous membrane – a. anticlinally elongated cells of the aquifer parenchyma; b. isodiametric cells of the aquifer parenchyma; c,d,f. vascular bundles with thick wall fibers; e. vascular bundles evidencing fibers with thin walls (arrow); g,j. stomata with closed ostiole; h,i. stomata with open ostiole. (ap = aquifer parenchyma; vb = vascular bundle; ch = chlorenchyma; fi = fibers; x = xylem; p = phloem). Scale bars: a,b = 250 μm; c-f = 50 μm; g-j = 100 μm (detail of the stomata = 25 μm).

The total thickness of the leaf, mesophyll, aquifer parenchyma, and chlorenchyma, as well as the height of the epidermal cells on the adaxial surface were significantly higher in plants developed in the greenhouse when compared to the in vitro grown plants, which did not differ statistically (Tab. 1). In addition, the epidermal cells on the abaxial surface were not significantly different in the leaves of plants developed in the greenhouse, and those grown in the tubes sealed with PM when compared to plants cultivated in the tubes sealed with PC and PVC (Tab. 1). Overall, the vascular bundles located at the leaves edges had more fibers associated with the xylem under all culture conditions (Fig. 2c-f). However, in the leaves of the plants grown in tubes sealed with PVC, the walls of these fibers were visually thinner (Fig. 2e).

The polar diameter of the stomata did not differ significantly under any culture conditions (Tab. 1). Nevertheless, the equatorial diameter was smaller in plants developed in tubes sealed with PM compared to those grown in the greenhouse. Consequently, the ratio between the polar diameter and the equatorial diameter was greater in the plants cultivated in tubes sealed with PM, whereas no significant differences were found for this parameter in the plants in vitro. The stomata of the plants grown under all treatments were elliptical (Tab. 1).

The stomatal density was significantly higher in leaves of plants grown in tubes sealed with PC compared to those obtained under all culture conditions. However, a stomatal index of leaves of plants grown in tubes sealed with PC was not significantly different to plants grown in greenhouse (Tab. 1).

The chlorenchyma cells of plants obtained in all treatments had typical organelles (Fig. 3a-f). We observed large central vacuoles, with other organelles adjacent to the cell walls (Fig. 3a). Mitochondria had well-developed crests (Fig. 3b-f), and were found associated to chloroplasts. The nuclei had conspicuous nucleoli and a similar shape in the cross-section of the leaf (Fig. 3b,c,e,f). Chloroplasts did not differ significantly in area among the treatments (Tab. 1). However, the shape of the chloroplasts, the organization of the internal membrane system, the number of starch grains, and the lipid bodies were different among the treatments.

Figure 3
a-f. Transmission electron micrographs showing cross-sections of the chlorenchyma of A. bromeliifolia leaves, evidencing typical structure and organelles of plant cells – a,b. plants grown in greenhouse; c. plants grown in test tubes sealed with rigid polypropylene cap; d,e. plants grown in test tubes sealed with polyvinyl chloride film; f. plants grown in test tubes sealed with rigid polypropylene cap with microporous membrane. (v = vacuole; ch = chloroplast; cw = cell wall; m = mitochondrion; st = starch grain; n = nucleus; nu = nucleolus; rib = ribosome). Scale bars: a = 5 μm; b = 0.5 μm (detail = 1μm); c,d = 1μm; e,f = 2 μm (detail = 0,5 μm)..

The chloroplasts of plants grown in the greenhouse were oval, and had a less appressed arrangement of thylakoid membranes and a high amount of starch grains and plastoglobules, both large-sized (Fig. 4a). The leaves of plants developed in vitro had homogeneously small plastoglobules (Fig. 4b-d) and a more appressed arrangement of thylakoid membranes when compared to the plants grown in the greenhouse (Fig. 4a-d). In plants grown in tubes sealed with PC, the chloroplasts were more elongated, and had large areas without thylakoids filled with the stroma (Fig. 4b). In plants developed in tubes sealed with PVC, the chloroplasts were semicircular, and the internal membrane system was irregularly arranged in some regions (Fig. 4c). Fewer chloroplasts contained starch grains in plants developed in tubes sealed with PVC and PC and, when present, they were smaller and less numerous (Figs. 3e; 4c). In tubes sealed with PM, the chloroplasts ranged from semicircular to oval, had large starch grains (Fig. 4d) and, in some regions, a less appressed arrangement of thylakoid membranes.

Figure 4
a-d. Transmission electron micrographs showing cross-sections of the chlorenchyma of A. bromeliifolia leaves, evidencing the chloroplasts – a. plants grown in greenhouse, chloroplasts with a large number and size of starch grains and lipid bodies; b. plants grown in test tubes sealed with rigid polypropylene cap, evidencing areas in the stroma without thylakoids (*); c. plants developed in test tubes sealed with polyvinyl chloride film, chloroplast with internal membrane system arranged irregularly in some regions (arrow), detail of appressed thylakoids; d. plants grown in test tubes sealed with rigid polypropylene cap with microporous membrane, evidencing chloroplasts with a large number of starch grains and internal membrane system less appressed in some regions. (st = starch grain; p = plastoglobuli; m = mitochondrion; cw = cell wall). Scale bars: a,b,d = 1 μm; c = 2 μm.

Discussion

In vitro culture influenced the morphology of leaves of A. bromeliifolia, which were more elongated, slender and delicate when compared to those grown under greenhouse conditions. This result corroborates those previously reported (Johansson et al. 1992Johansson M, Kronestedt-Robards EC & Robards AW (1992) Rose leaf structure in relation to different stages of micropropagation. Protoplasma 166: 165-176. ; Aoyama et al. 2012Aoyama EM, Versieux, LM, Nievola, CC & Mazzoni-Viveiros SC (2012) Avaliação da eficiência da propagação de Alcantarea imperialis (Bromeliaceae) cultivada in vitro e ex vitro. Rodriguésia 63: 321-331.). In response to in vitro environment, plant physiology and morphology are significantly different from those of the plants grown in natural environments (Kozai 2010Kozai T (2010) Photoautotrophic micropropagation - environmental control for promoting photosynthesis. Propagation of Ornamental Plants 10: 188-204. ). The thicker leaves developed in the greenhouse indicate increased cell expansion, since no significant difference was observed in the number of cell layers in the leaves of all analyzed plants. This result is probably related to the intensity of light inside the greenhouse. In fact, several studies have reported thickening of leaves due to cell expansion under higher light intensity (Voltan et al. 1992Voltan RBQ, Fahl JI & Carelli MLC (1992) Variação na anatomia foliar de cafeeiros submetidos a diferentes intensidades luminosas. Revista Brasileira de Fisiologia Vegetal 4: 99-105. ; Hanba et al. 2002Hanba YT, Kogami H & Terashima I (2002) The effect of growth irradiance on leaf anatomy and photosynthesis in Acer species differing in light demand. Plant, Cell & Environment 25: 1021-1030.; Lima Jr. et al. 2006Lima Jr EC, Alvarenga AA, Castro EM, Vieira VC & Barbosa JPRAD (2006) Aspectos fisioanatômicos de plantas jovens de Cupania vernalis Camb. submetidas a diferentes níveis de sombreamento. Revista Árvore 30: 33-41.; Fernandes et al. 2014Fernandes VF, Bezerra LA, Mielke MS, Silva DC & Costa LCB (2014) Anatomia e ultraestrutura foliar de Ocimum gratissimum sob diferentes níveis de radiação luminosa. Ciência Rural 44: 1037-1042.), with improved photosynthetic efficiency (Kim et al. 2005Kim GT, Yano S, Kosuka T & Tsukaya H (2005) Photomorphogenesis of leaves: shade-avoidance and differentiation of sun and shade leaves. Photochemical Photobiological Sciences 4: 770-774.). According to Hazarika (2006)Hazarika BN (2006) Morpho-phisiological disorders in in vitro culture of plants. Scientia Horticulturae 108: 105-120., the delicate structure of plants developed in vitro makes them more vulnerable when exposed to ex vitro conditions.

The leaves of A. bromeliifolia were anatomically similar under all culture conditions, and they are also similar to that reported for leaves of other species of Aechmea, grown under natural conditions (Proença & Sajo 2004Proença SL & Sajo MG (2004) Estrutura foliar de espécies de Aechmea Ruiz & Pav. (Bromeliaceae) do estado de São Paulo, Brasil. Acta Botanica Brasilica 18: 319-331.; Souza et al. 2005Souza GM, Estelita MEM & Wanderley MG L (2005) Anatomia foliar de espécies brasileiras de Aechmea subg. Chevaliera (Gaudich. ex Beer) Baker, Bromelioideae-Bromeliaceae. Revista Brasileira de Botânica 28: 603-613.; Silva & Scatena 2011Silva IV & Scatena VL (2011) Anatomia foliar de espécies de Bromeliaceae (Poales) da Amazônia, Mato Grosso, Brasil. Revista de Ciências Agro-Ambientais 9: 225-240.). Nonetheless, we observed that some characteristics in adult plants of A. bromeliifolia are different from those of young plants. The leaves of the adult plants are hypostomatic, the epidermis has peltate trichomes, the mesophyll has aeration channels continuous to the subestomatic chambers with braciform cells, and groups of extravascular fibers dispersed throughout the chlorenchyma (Proença & Sajo 2004). In addition, Proença & Sajo (2004) do not report the occurrence of glandular trichomes.

Despite the anatomical similarities, some characteristics differed between the leaves of A. bromeliifolia cultivated in vitro. The stomata of leaves of A. bromeliiflia grown both in a greenhouse and in tubes sealed with PM were closed by the time of collection (daytime period). Considering that A. bromeliifolia is a crassulacean acid metabolism (CAM) species (Griffiths & Smith 1983Griffiths H & Smith JAC (1983) Photosynthetic pathways in the Bromeliaceae of Trinidad: relations between life-forms, habitat preference and the occurrence of CAM. Oecologia 60: 176-184.; Scarano et al. 2002Scarano FR, Duarte HM, Rôças G, Barreto SMB, Amado EF, Reinert F, Wendt T, Mantovani A, Lima HRP & Barros CF (2002) Acclimation or stress symptom? An integrated study of intraspecific variation in the clonal plant Aechmea bromeliifolia, a widespread CAM tank-bromeliad. Botanical Journal of the Linnean Society 140: 391-401.), it is expected that stomata remain closed during the day under natural conditions. In contrast, the leaves of plants grown in tubes sealed with PC and PVC had opened stomata by the time of collection. The microporous membrane used in the PM sealing type allows greater amount of gas exchange per hour than other sealing types without membrane (Saldanha et al. 2012Saldanha CW, Otoni CG, Azevedo JLF, Dias LLC, Rêgo MM & Otoni WC (2012) A low-cost alternative membrane system that promotes growth in nodal cultures of Brazilian ginseng [Pfaffia glomerata (Spreng.) Pedersen]. Plant Cell, Tissue and Organ Culture 110: 413-422.), and this probably favors the proper functioning of A. bromeliifolia stomata.

The leaves of A. bromeliifolia grown in vitro had elliptical stomata, similar to what was observed in leaves grown in a greenhouse. However, this result is not common, since the stomata of plants grown in vitro are usually rounded, which is often associated with low functionality (Khan et al. 2003Khan PSSV , Kozai T , Nguyen QT, Kubota C & Dhawan V (2003) Growth and water relations of Paulownia fortunei under photomixotrophic and photoautotrophic conditions. Biologia Plantarum 46: 161-166.; Afreen 2005Afreen F (2005) Physiological and anatomical characteristics of in vitro photoautotrophic plants. In: Kozai T, Afreen F & Zobayed SMA (eds.) Photoautotrophic (sugar-free medium) micropropagation as a new micropropagation and transplant production system. Springer, Dordrecht. Pp. 61-90.), and incapacity to fully close when stimulated (Khan et al. 1999Khan PSSV, Evers D & Hausman JF (1999) Stomatal characteristics and water relations of in vitro grown Quercus robur NL 100 in relation to acclimatization. Silvae Genetica 48: 83-87. ). The elliptical stomata found in A. bromeliifolia are believed to have good functionality since they are characteristically found in plants grown under photoautotrophic conditions (Khan et al. 2003Khan PSSV , Kozai T , Nguyen QT, Kubota C & Dhawan V (2003) Growth and water relations of Paulownia fortunei under photomixotrophic and photoautotrophic conditions. Biologia Plantarum 46: 161-166.).

Plants developed in tubes sealed with PC had leaves with higher stomatal density. However, stomatal index of leaves from this condition was not significantly different from that observed in greenhouse leaves. This result suggests that the increase of stomatal density occurred due to a decrease on the expansion of ordinary epidermal cells. Greater stomatal density has been reported to occur due to high relative humidity in tubes with less ventilation (Zobayed et al. 2001Zobayed SMA, Armstrong J & Armstrong W (2001) Leaf anatomy of in vitro tobacco and cauliflower plantlets as affected by different types of ventilation. Plant Science 161: 537-548.; Mohamed & Alsadon 2010Mohamed MAH & Alsadon AA (2010) Influence of ventilation and sucrose on growth and leaf anatomy of micropropagated potato plantlets. Science Horticulturae 123: 295-300. ). Thus, the high number of stomata in plants grown in hermetically sealed tubes may be a strategy to enhance leaf transpiration, thus leading to higher uptake of water and nutrients.

The fibers associated with the vascular bundles in leaves of plants grown in tubes sealed with PVC were not very thick and this may provide less mechanical support for the plants during the process of acclimatization.

The in vitro environment affected the organization of chloroplasts of A. bromeliifolia, different from other organelles that were similar to those of plants gown in the greenhouse, as reported by Rodrigues et al. (2014)Rodrigues SP, Picoli EAT, Oliveira DC, Carneiro RGS & Isaias RMS (2014) The effects of in vitro culture on the leaf anatomy of Jatropha curcas L. (Euphorbiaceae). Bioscience Journal 30: 1933-1941.. The most frequent changes in the ultrastructure of leaf cells of plants cultivated in vitro are observed in the chloroplasts, which vary in shape, size, organization of the internal membrane system and number of starch grains (Wetzstein & Sommer 1982Wetzstein HY & Sommer HE (1982) Leaf anatomy of tissue-cultured Liquidambar styraciflua (Hamamelidaceae) during acclimatization. American Journal of Botany 69: 1579-1586. ; Lee et al. 1985Lee N, Wetzstein HY & Sommer HE (1985) Effects of quantum flux density on photosynthesis and chloroplast ultrastructure in tissue-cultured plantlets and seedlings of Liquidambar styraciflua L. towards improved acclimatization and field survival. Plant Physiology 78: 637-641.; Majada et al. 2002Majada JP, Fal MA, Tadeo F & Sánchez-Tamés R (2002) Effects of natural ventilation on leaf ultrastructure of Dianthus caryophyllus L. cultured in vitro. In vitro Cellular & Developmental Biology - Plant 38: 272-278.; Sáez et al. 2012bSáez PL , Bravo LA , Sáez KL, Sánchez-Olate M, Latsague MI & Ríos DG (2012b) Photosynthetic and leaf anatomical characteristics of Castanea sativa: a comparison between in vitro and nursery plants. Biologia Plantarum 56: 15-24. ; Kapchina-Toteva et al. 2014Kapchina-Toteva V, Dimitrova MA, Stefanova M, Koleva D, Kostov K, Yordanova ZP, Stefanov D & Zhiponova MK (2014) Adaptive changes in photosynthetic performance and secondary metabolites during white dead nettle micropropagation. Journal of Plant Physiology 171: 1344-1353. ; Stefanova et al. 2015Stefanova M , Koleva D & Ganeva T (2015) Variations in the chloroplast ultrastructure in in vitro-cultured Hypericum spp. plants. Bulgarian Journal of Agricultural Science 21: 300-304.).

Little appressed thylakoid membranes are typical of chloroplasts exposed to high light intensity (Yano & Terashima 2001Yano S & Terashima I (2001) Separate localization of light signal perception for sun or shade type chloroplast and palisade tissue differentiation in Chenopodium album. Plant and Cell Physiology 42: 1303-1310.; Fernandes et al. 2014Fernandes VF, Bezerra LA, Mielke MS, Silva DC & Costa LCB (2014) Anatomia e ultraestrutura foliar de Ocimum gratissimum sob diferentes níveis de radiação luminosa. Ciência Rural 44: 1037-1042.). The less appressed arrangement of thylakoid membranes in the chloroplasts of plants grown in the greenhouse may be associated with the formation of large starch grains which are due to high light exposure. Similarly, in the chloroplasts of Liquidambar styraciflua L. exposed to high light intensity, grana were poorly organized as a result of the presence of starch (Lee et al. 1985Lee N, Wetzstein HY & Sommer HE (1985) Effects of quantum flux density on photosynthesis and chloroplast ultrastructure in tissue-cultured plantlets and seedlings of Liquidambar styraciflua L. towards improved acclimatization and field survival. Plant Physiology 78: 637-641.).

The chloroplasts of A. bromeliiflia grown in tubes sealed with PC have large areas without thylakoids and the chloroplast development in tubes sealed with PVC have irregularly arranged inner membranes. The abnormal development of chloroplasts has been reported in plants grown in non-ventilated vessels (Majada et al. 2002Majada JP, Fal MA, Tadeo F & Sánchez-Tamés R (2002) Effects of natural ventilation on leaf ultrastructure of Dianthus caryophyllus L. cultured in vitro. In vitro Cellular & Developmental Biology - Plant 38: 272-278.). Several authors have reported changes in the ultrastructure of chloroplasts in response to ethylene (Toyama 1980Toyama S (1980) Electron microscope studies on the morphogenesis of plastids. X. ultrastructural changes of chloroplasts in morning glory leaves exposed to ethylene. American Journal of Botany 67: 625-635.; Fukuda & Toyama 1982Fukuda K & Toyama S (1982) Electron microscope studies on the morphogenesis of plastids. XI. Ultrastructural changes of the chloroplasts in tomato leaves treated with ethylene and kinetin. Cytology 47: 725-736.; Fan et al. 2013Fan ST, Yeh DM & Chen SJ (2013) Genotypic differences in post-storage photosynthesis and leaf chloroplasts in response to ethylene and 1-methylcyclopropene in Aglaonema. Postharvest Biology and Technology 76: 98-105.), which is a volatile plant hormone that accumulates due to lack of ventilation. In addition, chloroplasts of A. bromeliifolia grown in vitro have small and few plastoglobules. According to Sáez et al. (2012b)Sáez PL , Bravo LA , Sáez KL, Sánchez-Olate M, Latsague MI & Ríos DG (2012b) Photosynthetic and leaf anatomical characteristics of Castanea sativa: a comparison between in vitro and nursery plants. Biologia Plantarum 56: 15-24. these features are associated to the lower oxidative stress in the in vitro environment when compared to the greenhouse conditions.

In conclusion, the analysis showed that the in vitro environment influences the texture and thickness of the leaves, the functionality of stomata, and the ultrastructure of chloroplasts. However, plants grown in tubes sealed with PM were similar to those developed in the greenhouse, especially considering stomata opening, occurrence of starch grains and organization of the internal membrane system of chloroplasts.

1
Research conducted as part of Master’s degree of the first author.

5
ORCID: <https://orcid.org/0000-0003-2884-0792>

Area Editor: Dra. Georgia Pacheco

Acknowledgements

We are grateful to the staff at the Laboratório de Microscopia de Alta Resolução (LabMic) and the Centro Regional para o Desenvolvimento Tecnológico e Inovação (CRTI) for their technical assistance. This research was supported by the Goiás Research Foundation, Brazil (FAPEG, Proc. 201210267001075); and the Coordination for the Improvement of Higher Education Personnel Foundation (CAPES).

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Publication Dates

Publication in this collection
07 Feb 2020
Date of issue
2020

History

Received
31 Jan 2018
Accepted
20 Sept 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] 1
Research conducted as part of Master’s degree of the first author.

Parameter	Greenhouse	In vitro
Parameter	Greenhouse	PC	PVC	PM
Length of the aerial part [cm]	1,67 ± 2.61 c	6,22 ± 2.10 a	4.67 ± 1.00 b	7.70 ± 1.39 a
Number of leaves	4.91 ± 0.51 b	7.16 ± 1.26 a	6.66 ± 1.72 a	6.50 ± 1.00 a
Leaf thickness [µm]	1260.43 ± 133.85 a	772.42 ± 129.94 b	710.73 ± 135.33 b	814.46 ± 63.59 b
Mesophyll thickness [µm]	1130.23 ± 129.49 a	679.41 ± 126.06 b	612.72 ± 127.25 b	722.54 ± 64.17 b
Aquifer parenchyma thickness [µm]	464.52 ± 55.96 a	249.57 ± 52.62 b	199.39 ± 52.67 b	228.60 ± 55.81 b
Chlorenchyma thickness [µm]	669.84 ± 114 a	431.57 ± 93.53 b	416.09 ± 91.66 b	493.22 ± 35.39 b
Upper epidermis thickness [µm]	87.51 ± 9.86 a	57.39 ± 5.63 b	62.70 ± 7.23 b	59.12 ± 9.64 b
Lower epidermis thickness [µm]	53.90 ± 3.89 a	42.57 ± 6.77 b	41.84 ± 6.32 b	43.72 ± 6.37 ab
Polar diameter (PD) [µm]	62.55 ± 7.07 a	65.05 ± 6.39 a	66.01 ± 2.65 a	65.19 ± 3.12 a
Equatorial diameter (ED) [µm]	57.06 ± 3.92 a	50.79 ± 2.62 ab	52.58 ± 8.14 ab	46.81 ± 3.05 b
PD/ED [µm]	1.10 ± 0.10 b	1.28 ± 0.09 ab	1.28 ± 0.17 ab	1.40 ± 0.05 a
Stomatal density [mm²]	49.36 ± 6.93 bc	81.04 ± 14.40 a	52.96 ± 5.30 b	32.88 ±7.62 c
Stomatal index [%]	10.41 ± 1.17 ac	10.45 ± 1.61 a	8.06 ± 0.79 bc	7.16 ± 1.47 b
Chloroplast area [µm²]	12.29 ± 0.43 a	10.56 ± 1.42 a	12.98 ± 3.34 a	14.95 ± 0.90 a

Brasil