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1113 
Original Article 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1113-1118, Sept./Oct. 2017 

EFFECT OF MODIFYING CONCENTRATIONS OF CALCIUM AND 
MAGNESIUM ON in vitro DEVELOPMENT OF BANANA CV. PRATA-ANÃ 

(GENOMIC GROUP AAB) 
 

EFEITO DA MODIFICAÇÃO DAS CONCENTRAÇÕES DE CÁLCIO E MAGNÉSIO 
NO DESENVOLVIMENTO in vitro DE BANANEIRA CV. PRATA-ANÃ (GRUPO 

GENÔMICO AAB) 
 

Filipe Almendagna RODRIGUES1; Renata Alves Lara Silva REZENDE2; 
Joyce Dória Rodrigues SOARES3; Luciana Alves Caldeira BRANT4; 

 Tesfahun Alemu SETOTAW5; Moacir PASQUAL6, José Magno Queiroz LUZ7 
 1. Doutor em Agronomia/Fitotecnia, Universidade Federal de Lavras - UFLA, Lavras, MG, Brasil. filipealmendagna@yahoo.com.br; 2. 

Pós-doutoranda em Agronomia/Fitotecnia, UFLA, Lavras, MG, Brasil; 3. Professora, Doutora, Departamento de Agricultura, UFLA, 
Lavras, MG, Brasil; 4. Doutoranda em Agronomia/Fitotecnia, UFLA, Lavras, MG, Brasil; 5. Pós-doutorando em Agronomia/Fitotecnia, 

UFLA, Lavras, MG, Brasil; 6. Professor, Doutor, Departamento de Agricultura, UFLA, Lavras, MG, Brasil; 7. Professor, Doutor, 
Instituto de Ciências Agrárias - ICIAG - UFU, Uberlândia, MG, Brasil. 

 
ABSTRACT: Research suggests that the development of micropropagated banana plants can be improved by 

altering nutrient concentrations in the culture medium. The aim of this study was to evaluate the in vitro development of 
banana plants exposed to varying concentrations of calcium and magnesium sulfate. The shoot tips of banana cv. Prata-
Anã were inoculated in flasks (volume, 250 cm3) containing 50 mL of MS culture medium. The culture medium contained 
varying concentrations of CaCl2 (0, 220, 440, 880 mg L

-1) and MgSO4 (0, 185, 370, 740 mg L
-1. A completely randomized 

experimental design was employed, based on a 4 × 4 factorial scheme (four levels of CaCl2 concentration, and four of 
MgSO4). The MS culture medium containing 880 mg L

-1 of CaCl2 but no MgSO4 showed the highest increment in the 
number of leaves (6.0). The highest number of roots was observed in the absence of CaCl2 and MgSO4 in the medium. 
Additionally, the shoot length was longer (5.05 cm) when the MS medium was supplemented with 185 mg L-1 of MgSO4. 
The optimum in vitro development of banana cv. Prata-Anã was obtained when the MS medium was supplemented with 
880 mg L-1 of CaCl2 and 370 mg L

-1 of MgSO4. 
 
KEYWORDS: Musa spp. Tissue culture. Micropropagation. Mineral nutrition.  

 
INTRODUCTION 

 
In Brazil, one of the most cultivated and 

consumed fruits is the banana (REETZ et al., 2015). 
Brazil is the fourth largest producer of bananas after 
India, China, and the Philippines (OECD, 2015). 
Banana cultivation extends throughout all regions in 
Brazil, and the fruits provide a source of both 
income and food for producers (SILVA et al., 
2003). 

Currently, several banana cultivars are 
traditionally grown in Brazil (NOMURA et al., 
2013). However, the cultivar Prata-Anã (genomic 
group AAB) is most widely planted and consumed; 
it has a long tradition of cultivation in the country, 
and is well accepted by the market (DONATO et al., 
2009). 

It is difficult to expand the productivity of 
banana plantations using conventional methods, 
because the seedlings produced through 
conventional methods multiply at a low rate, and are 
also susceptible to diseases and pests (ROELS et al., 
2005). Propagation using in vitro methods is 

however a viable alternative, since it enables fast 
multiplication of a large number of seedlings that 
are of high phytosanitary quality, and are genetically 
superior and uniform. Micropropagation is therefore 
more frequently used than conventional methods in 
banana production, and is preferred by producers 
because of the high cost–benefit relationship.  

There is little information in the literature 
about the importance of mineral nutrients for the 
growth of banana plants in vitro (GRIBBLE et al., 
2002). There are several studies on mineral nutrition 
and its effect on banana plant growth and 
development. However, Souza and Gonçalves 
(1996) note the absence of systematic studies on 
adequate nutrient composition in the culture 
medium for different genotypes of banana plants.  

Banana is a nutrient-exigent plant, not only 
to facilitate rapid vegetative development, but also 
to ensure high biomass production and high levels 
of nutrient absorption. Synergism and antagonism 
between nutrients are well studied for banana. 
According to Borges (2004), the most researched 
interactions relating to banana plants concern 

Received: 18/11/16 
Accepted: 03/05/17 



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Effect of modifying concentrations…  RODRIGUES, F. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1113-1118, Sept./Oct. 2017 

potassium (K), calcium (Ca), and magnesium (Mg). 
Paula et al. (2015) report that banana plants 
cultivated in vitro absorb less K, and a similar 
quantity of Ca and Mg compared to plants cultivated 
ex vitro. However, it is fundamental to satisfactory 
in vitro development to maintain nutrient 
equilibrium in the culture medium.  

The Murashige and Skoog (MS) culture 
medium is one of the most utilized, for either 
micropropagation or other biotechnology 
techniques, in growing banana (MURASHIGE; 
SKOOG, 1962). Calcium chlorate (CaCl2), 
magnesium sulfate (MgSO4), and potassium sulfate 
(KH2PO4) have been identified as highly important 
reagents in the MS medium (WADA et al., 2015).  

Ca and Mg are the most important 
macronutrients for the banana plant. Ca is an 
important component of its cell walls; it is involved 
in membrane permeability, ensuring continued 
transpiration with the loose of turgidity (RAVEN et 
al., 2007). According to Prado (2008), Ca plays a 
role in cell wall formation by increasing mechanical 
resistance, thus supporting the acclimatization phase 
of the plant. Mg is present in chlorophyll molecules, 
and in leaf cell vacuoles, the organelles that contain 
10% of the total leaf Mg (MALAVOLTA, 2006). It 
is also a cofactor for various enzymes which act on 
phosphorylated substrates that are of great 
importance in energy metabolism. Additionally, Mg 
also stimulates hydrogenase, lyase, and mutase 
activity within the plant (MENGEL; KIRKBY, 
1987).  

Adelberg et al. (2013) indicated that an 
understanding of the relationship between nutrients 
is important to identifying the culture medium 
composition that best eliminates nutrient deficiency 
by optimizing micropropagation processes. In this 
context, modifying CaCl2 and MgSO4 in the culture 
medium could potentially improve development 
using micropropagation.  

Based on this hypothesis, the objective of 
this study was to evaluate and compare the in vitro 
development of banana cv. Prata-Anã when 
submitted to different concentrations of CaCl2 and 
MgSO4.  

 
MATERIAL AND METHODS 

 
Shoot tips of banana cv. Prata-Anã 

(genomic group AAB) were inoculated in flasks 
(volume, 250 cm3) containing 50 mL of MS culture 
medium (MURASHIGE; SKOOG, 1962), 
supplemented by different concentrations of CaCl2 
(0, 220, 440, and 880 mg L-1), and MgSO4 (0, 185, 
370, and 740 mg L-1). In addition, 1.8 g L-1 

Phytagel® (Sigma-Aldrich Co., St. Louis, MO, 
USA) was added to the culture medium, and the pH 
was adjusted to 5.8 before it was autoclaved (121°C, 
1 atm, for 20 min). Subsequently, the flasks were 
maintained in the growth room and illuminated with 
white fluorescent light (OSRAM 20W), with an 
irradiation of 42 W m-2, 16-hour photoperiod, and 
temperature of 25 ± 2°C.  

A completely randomized experimental 
design was used, with a 4 × 4 factorial scheme (for 
the four concentration levels of CaCl2, and four of 
MgSO4). Twelve plants were used (four plants for 
three replications) for each treatment. The number 
of shoots, number of roots, aerial section length 
(cm), root length (cm), number of leaves, and plant 
fresh weight (g) were evaluated after 45 days of 
culture.  

The data recorded were subjected to an 
analysis of variance and means separation test. The 
data revealed a significant difference between 
treatments subsequently submitted for regression 
analysis. All the statistical analysis was performed 
using Sisvar statistical analysis software 
(FERREIRA, 2011). 
 
RESULTS AND DISCUSSION 

 
A significant interaction was observed 

between CaCl2 and MgSO4 levels for all the 
variables studied, except root length.  

Figure 1 shows the standard behavior of in 
vitro cultured banana cv. Prata-Anã in the different 
treatments. The absence or use of a 220 mg L-1 level 
of CaCl2, when combined with different 
concentrations of MgSO4 (0, 185, 370, 740 mg L

-1), 
resulting in leaves appearing burnt. This was 
probably due to Ca deficiency, leading to chlorosis 
and necrosis in the young leaves. It is important to 
note that the only source of Ca present in the MS 
medium was CaCl2, at a concentration of 440 mg L

-

1.  
As Ca has a low mobility, symptoms of its 

deficiency were very severe in new leaves and the 
meristematic regions, resulting in tissue damage to 
or death of these growing parts (EPSTEIN; 
BLOOM, 2005). According to Arruda et al. (2000), 
this low Ca mobility could be due to its high 
concentration in the middle lamella of cell walls, 
and in the external region of the plasmatic 
membrane. Ca also plays an important role in 
morphogenesis, due to its interaction with growth 
regulator substances associated with cytokinin, 
mainly in the area where differentiation occurs. It 
can also assist in the detoxication of high 
concentrations of other mineral elements in the plant 



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Effect of modifying concentrations…  RODRIGUES, F. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1113-1118, Sept./Oct. 2017 

tissues. Ca is transported through passive processes 
that are influenced by the respiration rate 
(MCCOWN; SELLMER, 1987). Therefore, the 
necrotic symptoms observed in the terminal shoots 
mostly occurred as a result of low respiratory 

activity in the explants cultivated in vitro. However, 
these symptoms can be prevented by environmental 
modification of the culture using gas exchange, or 
by increasing Ca levels in the culture medium. 

 

 
Figure 1. Role of CaCl2 and MgSO4 in the in vitro development of banana cv Prata-Anã: A – absence of CaCl2, 

with 0, 185, 370, 740 mg L-1 of MgSO4; B – 220 mg L
-1 of CaCl2, with 0, 185, 370, 740 mg L

-1 of 
MgSO4; C – 440 mg L

-1 of CaCl2, with 0, 185, 370, 740 mg L
-1 of  MgSO4; D – 880 mg L

-1 of CaCl2, 
with 0, 185, 370, 740 mg L-1 of MgSO4. 
 

Sarkar et al. (2005) also found limited Ca 
translocation rates in potato plants in an in vitro 
culture. Since the transport of Ca in the xylem is 
dependent on plant transpiration, high air humidity 
in the in vitro environment can induce Ca deficiency 
in the aerial parts of micropropagated plants. It is 
probable that, among all macronutrients, Ca is most 
sensitive to problems in translocation, thereby 
impacting plant growth (WHITE; BROADLEY, 
2003) 

In our study, chlorosis was observed in 
mature leaves. This supports the rapid translocation 
of Mg from mature to younger plant parts; the visual 
symptoms of Mg deficiency therefore first appear in 
more mature leaves (EPSTEIN; BLOOM, 2005), in 
contrast to Ca, which accumulates in older organs 
due to its low mobility in the phloem 
(MALAVOLTA, 2006). 

A significant influence on the number of 
shoots (Figure 2A) was observed at concentrations 
of 370 mg L-1 of MgSO4, when combined with the 
various CaCl2 concentrations. As the concentration 
of CaCl2 increased, the number of shoots per explant 
reduced, from a mean value of 2.43 shoots in the 
absence of CaCl2. In contrast to our findings for 
banana cv. Prata-Anã, Adelberg et al. (2013) 
showed that increases in the concentration of CaCl2 
and MgSO4 promoted increased shoot numbers for 
turmeric (Curcuma longa L.).  

The number of roots (Figure 2B) reduced 
according to a quadratic form when 185 mg L-1 of 
MgSO4 was combined with increasing CaCl2 
concentrations. The maximum number of roots 
(mean value 4.98) was observed in the absence of 
CaCl2. For ions to be absorbed through the plant 
roots, it is necessary to establish ion-root contact 
through the processes of mass flow, diffusion, and 
radicular interception (ZELAZNY; VERT, 2014). It 
is likely that, in our study, banana cv. Prata-Anã 
increased the number of roots in order to promote 
radicular interception and absorption of Ca in the 
presence of lower Ca concentrations in the growing 
medium. This is supported by a reduction of 33.33% 
in the number of roots when concentrations of Ca in 
the medium were increased.  

A concentration of 370 mg L-1 of MgSO4 
was observed to promote an increase in shoot length 
(Figure 2C) with increasing concentrations of CaCl2, 
achieving a maximum value of 5.76 cm. In contrast, 
a concentration of 185 mg L-1 of MgSO4 promoted a 
reduction in shoot length. 

The number of leaves (Figure 2D) increased 
in the absence of MgSO4, or at a concentration of 
370 mg L-1 together with an increase in CaCl2 
concentration. A reduction in the number of leaves 
was observed at concentration of 880 mg L-1 of 
CaCl2.  



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Effect of modifying concentrations…  RODRIGUES, F. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1113-1118, Sept./Oct. 2017 

 

 
Figure 2. A) Number of shoots, B) number of roots, C) shoot length, D) number of leaves, and E) fresh weight 

of banana cv. Prata-Anã cultured in different concentrations of CaCl2 and MgSO4. Legend: ns = non-
significant. 
 

The fresh weight (Figure 2E) increased in a 
quadratic form when 370 mg L-1 of MgSO4 was 
used, achieving a maximum value of 3.19 g.  

In this study, the optimum results for 
number of shoots, shoot length, number of leaves, 
and fresh weight were observed when using 
concentrations of 880 mg L-1 of CaCl2, and 370 mg 
L-1 of MgSO4. This is demonstrated in Figure 2. In 
summary, our findings suggest that an MS medium 
with MgSO4 at its original concentration (370 mg L

-

1), but with twice the concentration of CaCl2 (880 
mg L-1), is the protocol that favors the optimum in 
vitro development of banana. 
 
CONCLUSION 

 
The optimum in vitro development of 

banana cv. Prata-Anã was obtained using an MS 
culture medium, containing 880 mg L-1 of CaCl2 and 
370 mg L-1 of MgSO4.  

 
 

RESUMO: Pesquisas sugerem que o desenvolvimento de plantas de bananeira podem ser melhoradas pela 
alteração das concentrações no meio de cultura. O objetivo deste estudo foi avaliar o desenvolvimento in vitro de 
bananeira submetida a diferentes concentrações de cloreto de cálcio e sulfato de magnésio. Ápices caulinares de bananeira 



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Effect of modifying concentrations…  RODRIGUES, F. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1113-1118, Sept./Oct. 2017 

cv. Prata-Anã foram inoculados em frascos (volume, 250 cm3) contendo 50 mL de meio de cultura MS. O meio de cultura 
contendo diferentes concentrações de CaCl2 (0, 220, 440 e 880 mg L

-1) e MgSO4 (0, 185, 370, 740 mg L
-1). O 

delineamento experimental foi inteiramente casualizado, em esquema fatorial 4 × 4 (quatro concentrações de CaCl2 e 
quatro de MgSO4). O meio MS contendo 880 mg L

-1 de CaCl2 na ausência de MgSO4 proporcionou maior incremento no 
número de folhas (6,0). Maior número de raiz foi observado na ausência de CaCl2 e MgSO4 no meio. Além disso, maior 
comprimento de parte aérea (5,05 cm) foi obtido em meio MS suplementado com 185 mg L-1 de MgSO4. O melhor 
desenvolvimento in vitro de bananeira cv. Prata-Anã foi obtido em meio MS suplementado com 880 mg L-1 de CaCl2 e 
370 mg L-1 de MgSO4.  

 
PALAVRAS CHAVE: Musa spp. Cultura de tecidos. Micropropagação. Nutrição mineral.  

 
 
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