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839 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

MORPHO-ANATOMY OF LEAVES AND YIELD OF PINEAPPLE PLANT IN 
INTERCROPPING WITH CASSAVA 

 
MORFOANATOMIA FOLIAR E PRODUTIVIDADE DE ABACAXIZEIRO 

CONSORCIADO COM MANDIOCA 
 

Roberto Aparecido CUSTÓDIO¹; Sebastião Elviro de ARAÚJO NETO²; 
 Paulo César Poeta FERMINO JUNIOR³; Romeu de Carvalho ANDRADE NETO4; 

 Irene Ferro SILVA5 
1. Engenheiro Agrônomo, Mestre, Técnico da Prefeitura de Ouro Preto, RO, Brasil. robcustodio@hotmail.com; 2. Professor, Doutor, 

Programa de Pós Graduação em Produção Vegetal, Universidade Federal do Acre, UFAC, Rio Branco, AC, Brasil. 
selviro2000@yahoo.com.br; 3. Professor, Doutor, Universidade Federal de Santa Catarina, Florianópolis, SC, Brasil; 4. Professor, 
Doutor, Pesquisador da Embrapa, Acre, Rio Branco, AC, Brasil; 5. Engenheira Agrônoma, Mestre, Egressa do Programa de Pós 

Graduação em Produção Vegetal, Universidade Federal do Acre - UFAC, Rio Branco, AC, Brasil. 
 

ABSTRACT: The aims of this study were to evaluate the effects of shade in pineapple plant with cassava, on 
the yields of pineapple fruit sand cassava roots, on the morph-anatomical variation, damage by solar radiation and 
chlorophyll content of pineapple leaves. Pineapple plants were cultivated in plots comprising three parallel row sunder 
different shade conditions provided by cassava plants grown at various spacings within single rows located on either side 
of the plots. The experiment was of a randomized block design with five treatments (cassava spacings of 0.50, 0.75, 1.00 
and 1.25 m and a pineapple monoculture) and four replications. Yields of fruits and roots, together with the morphological, 
chemical and histological characteristics of the "D" leaves of pineapple, were determined14 months after planting the 
pineapples plant. Data were submitted to analysis of variance with the Scott-Knott test or Friedman test (P< 0.05) and to 
regression analysis. Pineapple plants grown under the majority of shade conditions presented higher fruit weight and 
overall yield per hectare in comparison with plants grown in direct sunlight. The maximum productivities of pineapple 
fruit were achieved when cassava plants were spaced 0.75 m apart and, under these shade conditions, fruits were fully 
protected against burning by the sun. The “D” leaves of shaded plants were longer and thicker, with higher content of 
chlorophyll a and total chlorophyll, reduced stomatal density and dimensions of stomatal pores, narrower guard cells, 
thinner aquiferous hypodermis, and reduced abaxial and adaxial epidermis. The yield of cassava roots per plant increased 
linearly with increasing distance between the plants, but the yield per hectare decreased with decreasing plant density. 

 
KEYWORDS: Ananas comosus. Manihot esculenta. Phenotypic plasticity. Intercropping. 
 

INTRODUCTION 
 
Pineapple plant (Ananas comosus L. 

Merrill) is an herbaceous perennial that is well 
adapted to the climate and soil of tropical regions 
and is grown throughout the northern Brazilian state 
of Acre. Ecological cultivation of pineapple plant in 
this region is based on minimal addition of external 
inputs, and systems involving the use of green 
manure and intercropping with other species have 
been adopted widely as alternative forms of family 
farming (ANDRADE NETO et al., 2011). The 
pineapple plant in organic polyculture with passion 
fruit, maize and cassava represents a viable 
proposition as demonstrated by an average land-use 
efficiency of 2.65 (ARAÚJO NETO et al., 2014) 

One of the major problems in the culture of 
pineapple plant in tropical regions relates to the high 
levels of solar radiation that burn or scold the outer 
layers of the fruit particularly during the maturation 
stage. According to the National Plant Classification 
System supported by the Brazilian Ministry of 

Agriculture, the damage caused by fruit burning is 
considered a serious issue, which can result in a 
productivity loss of up to 70% depending on the 
harvesting season (CUNHA; HAROLDO, 2008). 

Although cultivation of crops under shade 
conditions may provide a solution to this problem, 
alterations in luminosity can induce different 
anatomical, physiological and biochemical 
responses in dissimilar plant species and, 
consequently, variations in growth and 
photosynthetic efficiency (KIM et al., 2005). In 
some cases, plants exposed to intense solar radiation 
exhibit greater plasticity with an enhancement in 
photosynthetic capacity (DUZ et al., 2004). For 
example, the thickness of leaf tissues, mainly the 
epidermis and chlorophyll parenchyma, may 
increase in order to improve the dissipation of 
excess radiation (MARKESTEIJN et al., 2007; 
SARIJEVA et al., 2007), or the stomata, which exert 
significant influence on photosynthesis and leaf 
temperature, may vary in size and density allowing 
better regulation of gas exchange and transpiration 

Received: 13/06/15 
Accepted: 20/01/16 



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(HETHERINGTON; WOODWARD, 2003; AL 
AFAS et al., 2006). In addition, the distribution and 
concentration of chlorophyll molecules are altered 
by solar irradiance (CARVALHO et al., 2010). In 
this manner, plasticity plays a significant role in the 
mechanism of plant adaptation to different light 
conditions. 

Shading a crop with multiple species in a 
polyculture system is considered by many 
researchers to be an advantageous method for 
augmenting productivity and increasing the revenue 
of an agricultural unit (BEZERRA NETO et al., 
2012) while, at the same time, reducing negative 
environmental impacts (CECÍLIO FILHO et al., 
2011; PYPERS et al., 2011). The aims of this study 
were to evaluate the effects of shade in pineapple 
plant with cassava, on the yields of pineapple fruit 
sand cassava roots, on the morph-anatomical 
variation, damage by solar radiation and chlorophyll 
content of pineapple leaves. 
 
 
 

MATERIAL AND METHODS 
 
The intercropping of pineapple plant 

(Smooth Cayenne group; cultivar Rio Branco 1) and 
cassava (cultivar BRS Caipora) was performed at 
the Sítio Ecológico Seridó, Rio Branco, Acre, Brazil 
(9º53’16’’ S, 67º49’11’’ W; altitude 170 m) during 
the period March 2011 to November 2012. The 
region presents a tropical monsoon climate of type 
Am according to the Köppen classification. The soil 
is categorized as yellow clay with plinthite 
(argissolo amarelo alítico plíntico) according to the 
Brazilian Soil Classification System, with moderate 
drainage and no apparent signs of erosion. Chemical 
analysis of horizon A (0 - 20 cm) revealed the 
following characteristics: pH 5.1; base saturation 
29%; organic matter 17 g dm-3; P 2 mg dm-3; K 1.8 
mmolc dm

-3; Ca 19 mmolc dm
-3; Mg 9 mmolc dm

-3; 
Al 8 mmolc dm

-3; H 64 mmolc dm
-3; Fe 530 mg dm-

3; Cu 1.6 mg dm-3; Mn 99 mg dm-3; Zn 2.6 mg dm-3 
and B 0.17 mg dm-3. 

The meteorological data recorded during the 
experiment are in Table 1.  

 
Table 1. Meteorological data of the city of River Bank in the years 2011 and 2012. (Collected by the weather 

station of the Federal University of Acre) 

Mês/Ano  
Precipitação 

(mm) 

Temperatura ºC Umidade  
Relativa 

(%) 
Evaporação  
total (mm) 

Insolação 
 (hora/décimos) 

Nebulosidade  
(%)  máxima mínima média 

01/2011 116.9 30.3 22.7 25.6 87 49.7 118.3 8.3 
02/2011 176.4 29.9 22.3 25.4 88 38.6 76.1 8.3 
03/2011 263.3 30.5 22.5 25.4 88 44.7 117.9 7.9 
04/2011 213.5 31.1 22.0 25.5 88 42.0 148.5 6.9 
05/2011 50.0 31.0 20.4 24.8 84 57.5 208.9 5.8 
06/2011 21.8 31.2 20.0 24.6 82 62.1 210.4 4.6 
07/2011 1.8 32.6 18.5 24.4 76 90.9 251.9 4.1 
08/2011 30.9 33.5 18.4 24.8 68 115.4 215.7 5.2 
09/2011 116.8 33.6 21.1 26.1 78 84.5 202.5 5.4 
10/2011 99.9 32.2 22.1 26.0 84 68.2 160.7 7.5 
11/2011 290.0 32.3 22.5 26.5 81 61.4 175.3 6.5 
12/2011 127.2 31.2 22.8 25.9 87 49.1 134.7 7.5 
01/2012 401.6 29.5 22.4 25.2 90 41.3 88.6 8.4 
02/2012 452.4 29.8 21.9 25.1 89 39.0 83.5 8.1 
03/2012 316.8 31.0 22.0 25.5 87 47.6 153.2 7.7 
04/2012 162.6 31.3 22.4 25.8 87 47.8 160.1 7.2 
05/2012 127.2 31.2 20.6 24.9 86 54.0 208.8 5.5 
06/2012 182.0 30.4 19.9 24.0 86 52.3 206.6 5.3 
07/2012 63.1 31.4 17.7 24.0 80 79.7 280.5 3.7 
08/2012 96.7 33.4 18.5 24.3 76 134.4 266.6 3.7 

Average 165.5 31.4 21.0 25.2 83.6 63.0 173.4 6.4 
 



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Morpho-anatomy of leaves…  CUSTÓDIO, R. A. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

The experiment was of a randomized block 
design and comprised five treatments  with four 
repetitions each encompassing three rows of 
pineapple plant and two rows of cassava. In March 
2011, following plowing and tilling of the 
experimental field, the pineapple propagules (500-
600 g each) were planted at 0.80 m spacings in three 
rows (0.25 m apart) according to the triangular 
arrangement. The external rows contained 24 
pineapple plants each while the central row, 
considered the applicable plot, contained 18 plants 
to give a total of 15,000 plants ha-1. The treatments 
consisted of different degrees of shade provided by 
cassava plants, the stems of which were planted in 
the first week of September 2011 in single rows 
located on either side of, and 0.20 m from, the 
external rows of pineapple plant. Different densities 
of cassava were obtained by varying the spacings 
between the plants: spacing 0.50 m, 14,280 plants 
ha-1; spacing 0.75 m, 9,520 plants ha-1; spacing 1.0 
m, 7,140 plants ha-1; and spacing 1.25 m, 5,712 
plants ha-1. In the control treatment, cassava plants 
were omitted so that the pineapple plant 
monoculture received direct sunlight. The cassava 
monoculture consisted of two rows (1.0 m apart) of 
plants with 1.0 m spacing (10,000 plants ha-1) and 
received similar agricultural management as the 
intercropping system. In all treatments, 2 m roads 
were located between the plots. 

Manual and mechanical weeding was 
performed (two and four times, respectively) as 
spontaneous weeds developed. No fertilizer was 
applied since the system intended to minimize the 
use of agricultural inputs. Infestation by fruit borers 
was controlled through application of a Bacillus 
thuringiensis-based insecticide (DiPel®) at the rate 
of 500 g ha-1 every 15 days from flowering to fruit 
maturation. Flowering of the pineapple plants was 
induced 14 months after planting by applying 5 mL 
of 2% urea and 0.15% Ethrel 720® to the center of 
the crown leaves by pressure spray. 

Morpho-anatomical analysis of “D” leaves 
from 14 month-old pineapple plants were performed 
in the Tissue Culture Laboratory of  Universidade 
Federal do Acre. Leaf length (cm) was determined 
by measuring the longitudinal axis from the base to 
the apex, whereas leaf area (cm2) was determined by 
tracing the contour of the leaf blade onto ordinary 
bond paper of constant density and cutting out the 
shapes so obtained. The area of the shape was 
calculated from the weight of the shape and the 
known density (75 g m-2) of the paper 
(VOLTOLINI; SANTOS, 2011). 

The extraction and quantitative analyses of 
chlorophylls were performed according to the 

method described by Arnon (1949). Fresh “D” 
leaves from 14 month-old plants (n = 3) were 
collected in the morning, packed in black plastic 
bags, labeled, stored in polystyrene boxes lined with 
aluminum foil and transported to the laboratory. 
Fresh tissue (0.5 g) was removed from the median 
region of the middle-third of the leaf and macerated 
in 80% acetone using a pestle and mortar. The 
extract was centrifuged at 2200 rpm for 2 min and 
the absorbance values at 654 and 663 nm of an 
aliquot of the supernatant were recorded using a 
spectrophotometer. The concentrations of 
chlorophylls a and b (Chla and Chlb, respectively) 
were determined according to equations 1 and 2, 
and the results expressed in terms of fresh weight 
(mg g-1). Values for total chlorophyll (Chltotal 
=Chla+Chlb) and the Chla/Chlb ratio were 
calculated, as follows:. 
Chla = {[(12.7 x A663nm – (2.69x645nm)]x 7mL} / 
[mass (mg)x 1000]  Eq. 1 
Chlb = {[(22.9 x A645nm – (4.48x663nm)]x 
7mL}/[mass (mg) x1000]  Eq. 2 

Descriptive microscopic analyses of the 
median regions of the middle-third of “D” leaves 
from 14 month-old plants (n = 3) were performed 
using an light microscope. Paradermal and cross 
sections of leaves were hand-cutusing sharp steel 
blades, stained with either Safranin-Astra blue 
(KRAUS; ARDUIN, 1997) or Sudan III (for 
histochemical detection of the epidermis), and 
mounted ontosemi-permanent slides using 
glycerinated gelatin. Images of the paradermal and 
cross sections were projected onto white paper with 
the aid of a Zeiss Opton camera attached to the 
microscope, and the thicknesses of the tissues and 
stomata, respectively, were estimated using a 
micrometer scale. The contours of the cells of the 
epidermis, hypodermis and chlorophyll parenchyma 
were copied and measured. 

Temporary slides of the abaxial surfaces of 
leaves were prepared with colorless varnish to allow 
examination of frontal views of the epidermis and to 
determine stomatal densities and the dimensions of 
guard cells and stomatal pores (BARBOZA et al., 
2006). Images of known areas (200 x 200 µ m) were 
projected as described above and the numbers of 
stomata per mm2 contained therein were counted. 
The lengths (longitudinal axis between the poles) 
and widths (transversal axis at the mid portion of the 
cell) of the guard cells were measured, and the 
dimensions of the stomatal pores evaluated. 

The mean masses of pineapple fruit (kg 
fruit-1) and cassava roots (kg plant-1) were 
determined by weighing the organs produced by the 
individual plants grown in that plot and multiplied 



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Morpho-anatomy of leaves…  CUSTÓDIO, R. A. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

by the number of plants distributed in a hectare. The 
percentage of fruits damaged by solar radiation was 
established by counting those that presented a 
yellowish color on the surface that had been 
exposed to the sun. 

Land-use efficiency was determined from 
the sum of the quotients of intercropping yield (B) 
and monoculture yield (M) calculated for each 
species according to equation 3: 

cassava

cassava

pineapple

pineapple

M

B

M

B
efficiency use-Land += Eq. 3 

Analysis of variance (ANOVA) was 
performed on the original data since the 
assumptions of normality of residuals and 
homogeneity of variances were obeyed, with the 
exception of those relating to sunburned fruits. 
When an F value indicated a difference between 
treatments, mean values were compared using the 
Scott-Knott test at the 5% probability level for 
qualitative factors (intercropping/monoculture 
systems) and regression analysis was carried for the 

quantitative factors (shading treatments). Data 
relating to the percentages of fruits exhibiting 
damage from sun light were heteroscedastic and 
were analyzed using the non-parametric Friedman 
test at the 5% probability level. 
 
RESULTS AND DISCUSSION 

 
The variations in the morphological and 

chemical characteristics of the “D” leaves of 
pineapple are presented in Table 2. The leaves of 
plants cultivated under higher levels of shading in 
spacings between the cassava plants: 0.50 m; 0.75 m 
and 1.0 m, were significantly (P <0.05) longer than 
those grown under less shade (spacing 01.25 m) or 
in sunlight (pineapple monoculture). Such increased 
length represents a phototropic response associated 
with the optimization of photosynthetic performance 
(TAKEMIYA et al., 2005). Interestingly, the areas 
of “D” leaves were not influenced significantly by 
any of the treatments.  

 
Table 2. Morphological and chemical characteristics of “D” leaves from 14 month-old pineapple plants 

(Smooth Cayenne group, cultivar Rio Branco 1) cultivated under various degrees of shade provided 
by cassava plants 

Spacing (m) 
Variable 1 

Length 
(cm) 

Area 
(cm2) 

Chla 
(mg g-1) 

Chlb 
(mg g-1) 

Chla/Chlb 
ratio 

Chltotal 
(mg g-1) 

0.50 105.0a 465.5a 0.86a 0.30a 3.01a 1.18a 
0.75 105.0a 448.0a 0.85a 0.31a 2.80a 1.19a 
1.00 105.7a 472.2a 0.94a 0.31a 3.13a 1.26a 
1.25 98.7b 431.3a 0.70b 0.26a 2.82a 0.98b 

Monoculture 97.0b 453.2a 0.69b 0.30a 2.33a 0.99b 
CV (%) 4.36 10.67 9.49 10.27 11.76 8.02 
F value 2 3.376* 0.433ns 8.148** 2.473ns 3.407* 7.821** 

1 Within a column, mean values (n = 60) bearing similar superscript lowercase letters are not significantly different (Scott-Knott test; P 
<0.05); 2Values classified as not significant (ns), significant at 5% (*) or significant at 1% (**); Abbreviations: Chl, chlorophyll; CV, 
coefficient of variation. 

 
Concentrations of Chla and Chltotal were 

significantly (P<0.05) lower in the leaves of 
pineapple plants that had received minimal shading 
(1.25 m) or had been exposed to direct sunlight 
(Monoculture). According to Almeida et al. (2005), 
the lower accumulation of chlorophyll in such 
leaves compensates for the higher levels of light 
intensity. Under conditions of appropriate radiation, 
chlorophyll molecules are synthesized and degraded 
at the same rate, but in the presence of excess 
sunlight, the rate of degradation is intensified 
(FERREIRA et al., 2012). No differences between 
treatments were observed with respect to the 

concentrations of Chlb or Chla/Chlb ratios (Table 
2). 

The “D” leaves of pineapple were 
hypostomatic (Figure 1A) with stomata distributed 
in parallel layers (Figures 1B and 1C) as described 
by Barboza et al. (2006). The abaxial (Figure 1D) 
and adaxial (Figure 1E) epidermal surfaces were 
unistratified, un curled and consisted of cells with 
thick anticlinal cell walls but without chlorophyll 
(PROENÇA; SAJO, 2007). The mesophyll 
exhibited dorsiventral organization, with the 
aquiferous hypodermis immediately adjacent to the 
adaxial epidermis present in grounded, thin walled 
non-chlorophyllous cells, sub adjacent layers of 



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Morpho-anatomy of leaves…  CUSTÓDIO, R. A. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

elongated anticlinal cells (PROENÇA; SATO, 
2007) and chlorophyll parenchyma distributed under 

the aquifer hypodermis in the form of rounded cells 
organized as a palisade. 

 

 
Figure 1. Microscopic analysis of a pineapple leaf blade: (A) Cross section showing the adaxial (ADE) and 

abaxial (ABE) epidermis, the aquiferous hypodermis (AH) and the chlorophyll parenchyma (CP); 
(B) Paradermal section showing the stomata arranged in longitudinal layers; (C) Paradermal section 
showing the frontal view of a stoma; (D) Cross section showing ABE; (E) Cross section showing 
ADE. Bar = 200 µ m (A and B), 20 µ m (C), 50 µ m (D and E). 

 
The variations in the histological 

characteristics of the “D” pineapple leaves are 
presented in Table 3. The thicknesses of the 
mesophyll and the leaf blade of pineapple were 
significantly greater (P <0.05) in plants grown under 
shade (0.50 at 1.25 m) in comparison with those grown 
in the sunlight (monoculture). Increases in the 
thicknesses of these tissues were associated with the 
significant expansion (P <0.05) of the aquiferous 
hypodermis under conditions of reduced light 
intensity. According to Rozendaal et al (2006), plants 
developed in shaded environments invest 
more in light-capturing complexes, while expansion 

of the aquiferous hypodermis layer reportedly 
assists in the scattering of diffuse light under 
conditions of low radiance (MARKESTEIJN et al., 
2007). No alterations in the chlorophyll parenchyma 
were observed in any of the treatments (Table 3). 

The thicknesses of the abaxial and adaxial 
epidermal layers of leaves of pineapple plants 
cultivated under direct sunlight were significantly (P 
<0.05) greater in comparison with plants grown under 
shade conditions (0.50 at 1.00 m spacings) (Table 3). 
Increased thickness of the epidermis represents a 
structural adaptation to minimize the effect of high 
solar radiation (MARKESTEIJN et al., 2007) and 



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Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

constitutes an important parameter in the adaptation 
of a plant to the variation in light intensity 

(ROZENDAAL et al., 2006; SARIJEVA et al., 
2007). 

 
Table 3. Histological characteristics of “D” leaves from 14 month-old pineapple plants (Smooth Cayenne 

group, cultivar Rio Branco 1) cultivated under various degrees of shade provided by cassava plants 

Variable1 
Cassava spacings2 

CV 
(%) 

F value2 
0.50 0.75 1.00 1.25 

pineapple 
monoculture 

Thickness of mesophyll (µm) 1.944a 1.999a 2.033a 2.042a 1.748b 5.36 5.365* 

Total thickness of leaf blade (µ m) 1.966a 2.020a 2.054a 2.066a 1.776b 5.29 5.145* 

Thickness of aquiferous hypodermis (µ m) 803a 848a 866a 867a 570b 6.80 24.580** 

Thickness of chlorophyll parenchyma (µ m) 1.206a 1.172a 1.187a 1.199a 1.206a 5,12 0.208ns 

Thickness of abaxial epidermis (mµ ) 10.5b 10.5b 9.9b 11.2b 13.3a 8.16 8.114** 

Thickness of adaxial epidermis (mµ ) 11.1b 10.9b 10.7b 12.6a 14.8a 10.33 7.849** 

Stomatal density(stoma mm-2) 92.7b 81.5c 93.1b 108.9a 116.2a 6.57 18.581** 

Length of stomatal pore (mµ ) 15.78b 15.61b 15.26b 15.62b 16.67a 2.29 4.235* 

Width of stomatal pore (mµ ) 1.49b 1.38b 1.54b 1.48b 1.83a 2.90 11.591** 

Length of guard cells (mµ ) 33.54a 32.54a 32.97a 32.57a 34.29a 2.26 3.093ns 

Width of guard cells (mµ ) 13.36b 13.05b 13.13b 13.33b 14.29a 2.26 10.333** 
1Within a row, mean values (n= 120) bearing similar superscript lowercase letters are not significantly different (Scott-Knott test; P 
<0.05); 2 Values classified as not significant (ns), significant at 5% (*) or significant at 1% (**); Abbreviation: CV, coefficient of 
variation. 

 
Stomatal density in pineapple leaves tended 

to increase in plants grown under conditions of 
greater luminosity (1.00 m of spacing and pineapple 
monoculture), with values ranging from 81.5 stoma 
mm2 in shaded areas to 116.2 stoma mm2 in direct 
sunlight. Increased stomatal density in plants 
cultivated under high light intensity is a mechanism 
of adaptation to optimize long-term gas exchange 
and photosynthetic activity under such conditions 
(SCHLUETER et al., 2003). 

The lengths and widths of the stomatal 
pores were significantly (P> 0.05) greater in the 
leaves of pineapple plants grown in sunlight 
compared with those of shaded plants. While, the 
lengths of guard cells were similar for all leaves 
analyzed, irrespective of shade treatment, the widths 
of these cells were significantly (P> 0.05) greater in 
leaves from plants grown in sunlight, and this may 
reflect the increased dimensions of the stomatal 
pores (Table 3). According to Hetherington and 
Woodward (2003), morphological alterations in the 
stomatal pores and guard cells may be associated 
with the increased stomatal conductance in leaves 
exposed to high solar radiation, constituting a 
strategy to increase transpiration efficiency and 
reduce leaf temperature. 

As expected, the percentage of sunburned 
pineapple fruits was significantly (P < 0.05) greater 
in plants cultivated in direct sunlight (pineapple 
monoculture) compared with shade-grown plants 
(Table 4). The spacing of 0.75 m between cassava 
shade plants, provided not only the best protection 
against solar radiation but also generated fruits with 
the highest mean mass and with the highest yield 
per hectare. 

In the intercropping system, the yield of 
cassava roots per plant exhibited a direct linear 
correlation with the distance apart of the plants, 
while the yield of roots per ha showed an inverse 
linear correlation with plant spacing (Figure 2). 
Although the yield per plant increased by 2.2 kg for 
each additional m of plant spacing, the 
corresponding yield per ha was reduced by 
10,068.99 kg. Thus, decreasing the density of plants 
from 14.280 plants ha-1 (0.5 m spacing) to 5.712 
plants ha-1 (1.25 m spacing) resulted in a reduction 
in total yield even though the yield per plant was 
higher in the latter situation. In high-density crops, 
the self-shaded plants have to compete for the 
limited light that filters through the canopy, and this 
reduces the photosynthetic activity and 
consequently the yield (AGUIAR et al., 2011). 

 



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Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

Table 4. Yields of pineapple fruits from 14 month-old pineapple plants (Smooth Cayenne group, cultivar Rio 
Branco 1) cultivated under various degrees of shade provided by cassava plants 

Cassava 
spacings 

Sunburned fruit1 
(%) 

Mean mass of fruit2 (kg 
fruit-1) 

Yield of fruit2 
(kg ha-1) 

Land-use 
efficiency1 

0.50 2.5b 1.368b 18,606.25b 2.04a 
0.75 0.0b 1.635a 24,501.53a 2.12a 
1.00 10.6b 1.233b 18,462.10b 1.71b 
1.25 0.0b 1.315b 19,702.08b 1.75b 

Pineapple 
monoculture 

45.0a 1.240b 18,606.25b - 

CV (%) - 10.05 14.27 6.67 
F value4 - 4.098* 4.105* - 

1 Within a column, mean values bearing similar superscript lowercase letters are not significantly different (non-parametric Friedman 
test; P <0.05); 2 Within a column, mean values bearing similar superscript lowercase letters are not significantly different (Scott-
Knott test; P <0.05); 3 Values classified as significant at 5% (*). 

 
 

 
Figure 2. Yield of cassava in intercropping with pineapple plant. The differences between treatments were 

significant in terms of yield per plant (** F at 1% probability = 25.284) and yield per unit area (* F at 
5% probability = 3.976). 

 
Land-use efficiency values were > 1 for all 

intercropping systems (Table 4), indicating that 
between 1.71 to 2.12 ha of the monocultures would 
be required to produce the same amount as 1 ha of 
the intercropping. The highest land-use-efficiency 
was obtained with shade in 0.75 m spacing followed 
closely by 0.50 m spacing. 

Along with increased yield, the intercropping 
system offers the additional advantage of diversity 
of products with dual purpose. According to Grisa 
(2007), agricultural systems of this type allow for 
greater food and economic security in family 
farming since products such as cassava have 
exchange value, if market prices are favorable, or 
may be consumed by the family in order to 
minimize expenditure on food at the market. 

Additionally, the sale of highly marketable products 
such as pineapple guarantees reimbursement of 
expenses for services and external inputs, and 
produces investment in property. 

 
CONCLUSIONS 

 
Pineapple plants grown under conditions of 

shade created by adjacent cassava plants presented 
phenotypic plasticity and exhibited longer and 
thicker “D” leaves with higher chlorophyll content, 
reduced stomatal density and dimensions of 
stomatal pores, narrower guard cells, thinner 
aquiferous hypodermis, and reduced abaxial and 
adaxial epidermis.  



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Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

The maximum yield of pineapple fruit, was 
achieved using an intercropping system in which 
shade was provided by cassava plants spaced 0.75 m 
apart. Under these conditions, fruits were fully 
protected against damage by solar radiation.  

The yield of cassava roots per plant 
increased linearly with increasing distance between 
the plants, but the yield per ha decreased with 
decreasing plant density. 

ACKNOWLEDGMENTS  
 
The authors are grateful to the Coordenação 

de Aperfeiçoamento de Pessoal de Nível Superior 
(CAPES) and the Conselho Nacional de 
Desenvolvimento Científico e Tecnológico (CNPq) 
for grants awarded to the authors.  

 
 
RESUMO: Os objetivos desse trabalho foram avaliar o efeito do sombreamento no abacaxizeiro com mandioca, 

sobre a produtividade de abacaxi e raízes de mandioca, sobre a variação morfoanatômica, queimadura do abacaxi pela 
radiação e os teores de clorofilas nas folhas do abacaxizeiro. As plantas de abacaxizeiro foram cultivadas em parcelas 
compreendendo linhas triplas paralelas (segundo um arranjo triangular) sob diferentes condições de sombreamentos 
proporcionadas por plantas de mandioca cultivadas em linhas simples em cada lado das parcelas. O delineamento utilizado 
foi de blocos casualizados com cinco tratamentos (sombreamento com mandioca em espaçamentos de 0,50, 0,75, 1,00 e 
1,25 m e monocultivo de abacaxi) e quatro repetições. As produtividades de abacaxi e mandioca, juntamente com as 
características morfológicas, químicas e histológicas da folhas “D” dos abacaxizeiros, foram determinadas 14 meses após 
o plantio. Os dados foram submetidos à análise de variância com teste de Scott-Knott ou teste de Friedman (P< 0,05) bem 
como análise de regressão. Abacaxizeiros cultivados sob sombreamento produziram frutos com maior peso médio e maior 
produtividade por hectare em comparação com plantas cultivadas sob luz solar direta. A máxima produtividade de abacaxi 
foi alcançada quando o espaçamento entre as plantas de mandioca foi de 0,75 m e, sob essas condições, os frutos ficaram 
completamente protegidos da radiação solar. As folhas “D” dos abacaxizeiros sombreados foram mais longas e espessas, 
apresentaram maior concentração de clorofila a e total, densidade estomática reduzida, poros estomáticos menores, células 
guarda mais estreitas, hipoderme aquífera mais fina e epidermes abaxial e adaxial reduzidas. A produtividade de mandioca 
por planta aumentou linearmente com o espaçamento crescente, porém a produtividade por hectare diminuiu com o 
decréscimo da densidade das plantas. 

 
PALAVRAS CHAVE: Anana comosus. Manihot esculenta. Plasticidade fenotípica. Cultivo  consorciado. 
 
 

REFERENCES 
 
AGUIAR, E. B.; VALLE, T. L.; LORENZI, J. O.;  KANTHACK, R. A. D.; MIRANDA FILHO, H.; GRANJA, 
N. do P. Efeito da densidade populacional e época de colheita na produção de raízes de mandioca de mesa. 
Bragantia, Campinas, v. 70, n. 3, p. 561-569, 2011. http://dx.doi.org/10.1590/S0006-87052011000300011 
http://dx.doi.org/10.1590/S0006-87052011005000010 
 
AL AFAS, N.; MARRON, N.; CEULEMANS, R. Clonal variation in stomatal characteristics related to 
biomass production of 12 poplar (Populus) clones in a short rotation coppice culture. Environmental and 
Experimental Botany, Amsterdã, n. 58, p. 279-286, 2006. 
 
ALMEIDA, S. M. Z.; SOARES, A. M.; CASTRO, E. M. de; VIEIRA, C. V.; GAJEGO, E.B. Alterações 
morfológicas e alocação de biomassa em plantas jovens de espécies florestais sob diferentes condições de 
sombreamento. Ciência Rural, Santa Maria, v. 35, n. 1, p. 62-68, 2005. http://dx.doi.org/10.1590/S0103-
84782005000100010 
 
ANDRADE NETO, R. C.; NEGREIROS, J. R. S.; ARAÚJO NETO, S. E. de; CAVALCANTE, M. J. B.; 
ALECIO, M. R.; SANTOS, R. S. Diagnóstico da potencialidade da fruticultura no Acre. Rio Branco, AC: 
Embrapa Acre (Série Documentos - EMBRAPA), 2011. 
 
ARAÚJO NETO, S. E. de; CAMPOS, P. A.; TAVELLA, L. B.; SOLINO, A. J. da S.; SILVA, I. F. Organic 
polyculture of  passion  fruit,  pineapple, corn  and  cassava:  the  influence  of  green manure  and  distance  
between  espaliers. Ciência & Agrotecnologia, Lavras, v. 38, n. 3, p. 247-255, maio./jun., 2014. 
http://dx.doi.org/10.1590/s1413-70542014000300004 



847 
Morpho-anatomy of leaves…  CUSTÓDIO, R. A. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

 
ARNON, D. I. Copper enzymes in isolated chloroplasts: polyphenoloxydase in Beta vulgaris. Plant 
Physiology, Maryland, v. 24, n. 1, p. 1-15, 1949. http://dx.doi.org/10.1104/pp.24.1.1 
 
BARBOZA, S. B. S. C.; GRACIANO-RIBEIRO, D.; TEIXEIRA, J. B. PORTES, T.A.; SOUZA, L. A. C. 
Anatomia foliar de plantas micropropagadas de abacaxi. Pesquisa Agropecuária Brasileira, Brasília, DF, v. 
41, n. 2, p. 185-194,2006. http://dx.doi.org/10.1590/S0100-204X2006000200002 
 
BEZERRA NETO, F.; PORTO, V. C. N.; GOMES, E. G.; CECÍLIO FILHO, A. B.; MOREIRA, J. N. 
Assessment of agroeconomic indices in polycultures of lettuce, rocket and carrot through uni and multivariate 
approaches in semi-arid Brazil. Ecological Indicators, v. 14, n. 1, p. 11–17, 2012. 
http://dx.doi.org/10.1016/j.ecolind.2011.07.006 
 
CARVALHO, R. F.; TAKAKI, M.; AZEVEDO, R. A. Plant pigments: the many faces of light perception. Acta 
Physiologiae Plantarum, Kraków, v. 33, n. 2, p. 241-248, 2010. http://dx.doi.org/10.1007/s11738-010-0533-7 
 
CECÍLIO FILHO, A. B.; REZENDE, B. L. A.; BARBOSA, J. C.; GRANGEIRO, L. C. Agronomic efficiency 
of intercropping tomato and lettuce. Anais da Academia Brasileira de Ciências, v. 83, n. 3, p. 1109-1119, 
2011. http://dx.doi.org/10.1590/S0001-37652011000300029 
 
CUNHA, G. A. P. DA; HAROLDO, D. Cuidados para evitar queima solar no abacaxi. Revista Frutas e 
derivados, Ano 3, Edição 9, p. 17, 2008. 
 
DUZ, S. R.; SIMINSKI, A.; SANTOS, M.; PAULILO, M. T. Crescimento inicial de três espécies arbóreas da 
Floresta Atlântica em resposta à variação na quantidade de luz. Revista Brasileira de Botânica, São Paulo, v. 
27, n. 3, p. 587-596, 2004. http://dx.doi.org/10.1590/s0100-84042004000300018 
 
FERREIRA, W. N.; ZANDAVALLI, R. B.; BEZERRA, A. M. E.; MEDEIROS FILHO, S. Crescimento inicial 
de Piptadenia stipulacea (Benth.) Ducke (Mimosaceae) e Anadenanthera colubrina (Vell.) Brenan var. cebil 
(Griseb.) Altshul (Mimosaceae) sob diferentes níveis de sombreamento. Acta Botanica Brasilica, Feira de 
Santana, v. 26, n. 2, p. 408-414, 2012. 
 
GRISA, C. Para além da alimentação: papeis e significado da produção para autoconsumo na agricultura 
familiar. Revista Extensão Rural, Porto Alegre, v. 14, p. 13-54, 2007. 
 
HETHERINGTON, A. M.; WOODWARD, F. I. The role of stomata in sensing and driving environmental 
change. Nature, Lancaster, v. 424, p. 901-908, 2003. http://dx.doi.org/10.1038/nature01843 
 
KIM, G.; YANO, S.; KOZUKA, T.; TSUKAYA, H. Photomorphogenesis of leaves: shade-avoidance and 
differenciation of sun and shade leaves. Photochemetry, Photobiology and Science, Cambridge, v. 4, n. 5, p. 
770-774, 2005. http://dx.doi.org/10.1039/b418440h 
 
KRAUS, J. E.; ARDUIN, M. Manual básico de métodos em morfologia vegetal. Seropédica: Editora 
Universidade Rural, 1997. 
 
MARKESTEIJN, L.; POORTER, L.; BONGERS, F. Light-dependent leaf trait variation in 43 tropical dry 
forest tree species. American Journal of Botany. St. Louis v. 94, n. 4, p. 515–525, 2007. 
http://dx.doi.org/10.3732/ajb.94.4.515 
 
PROENÇA, S. L.; SAJO, M das G. Anatomia foliar de bromélias ocorrentes em áreas de cerrado do Estado de 
São Paulo, Brasil. Acta Botanica Brasílica, Feira de Santana, v. 21, n. 3, p. 657-673, 2007. 
 
PYPERS, P.; SANGINGAB, J. M.; KASEREKAB, B.; WALANGULULUC, M.; VANLAUWEA, B. 
Increased productivity through integrated soil fertility management in cassava–legume intercropping systems in 



848 
Morpho-anatomy of leaves…  CUSTÓDIO, R. A. et al. 

Biosci. J., Uberlândia, v. 32, n. 4, p. 839-848, July/Aug. 2016 

the highlands of Sud-Kivu, DR Congo. Field Crops Research, v. 120, p. 76–85, 2011. 
http://dx.doi.org/10.1016/j.fcr.2010.09.004 
ROZENDAAL, D. M. A.; HURTADO, V. H.; POORTER, L. Plasticity in leaf traits of 38 tropical tree species 
in response to light; relationships with light demand and adult stature. Functional Ecology, London, v. 20, n. 2, 
p. 207-216, 2006. http://dx.doi.org/10.1111/j.1365-2435.2006.01105.x 
 
SARIJEVA, G.; KNAPP, M.; LICHTENTHALER, H. K. Differences in photosynthetic activity, chlorophyll 
and carotenoid levels, and in chlorophyll fluorescence parameters in green sun and shade leaves of Ginkgo and 
Fagus. Journal of Plant Physiology, Ohio, v. 164, n. 7, p. 950 – 955, 2007. 
http://dx.doi.org/10.1016/j.jplph.2006.09.002 
 
SCHLUETER, U.; MUSCHAK, M.; BERGER, D.; ALTMANN, T. Photosynthetic performance of an 
Arabidopsis mutant with elevated stomatal density (sdd1-1) under different light regimes. Journal of 
Experimental Botany, Oxford, v. 54, n. 383, p. 867-874, 2003. http://dx.doi.org/10.1093/jxb/erg087 
 
TAKEMIYA, A., INOUEA, S., DOIB, M., KINOSHITAA, T., SHIMAZAKIA, K. Phototropins promote plant 
growth in response to blue light in low light environments. The Plant Cell, Waterbury, v. 17, p. 1120-1127, 
2005. http://dx.doi.org/10.1105/tpc.104.030049 
 
VOLTOLINI, C. H.; SANTOS, M. Variações na morfoanatomia foliar de Aechmea lindenii (E. Morren) Baker 
var. lindenii (Bromeliaceae) sob distintas condições ambientais. Acta Botanica Brasilica, Feira de Santana, v. 
25, n. 1, p. 2-10, 2011. http://dx.doi.org/10.1590/S0102-33062011000100002