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1147 
Original Article 

Biosci. J., Uberlândia, v. 34, n. 5, p. 1147-1157, Sept./Oct. 2018 

EFFECT OF SHADING ON Dimorphandra gardneriana TUL. SEEDLING 
PRODUCTION 

 
EFEITO DO SOMBREAMENTO NA PRODUÇÃO DE MUDAS DE Dimorphandra 

gardneriana TUL. 
 

Sueli da Silva SANTOS-MOURA1; Edna Ursulino ALVES2; Marina Matias URSULINO3; 
Riselane de Lucena Alcântara BRUNO2; Antônio Pereira dos ANJOS NETO4 

1. Professor at the Federal Institute of Alagoas (IFAL), Brazil. sssantosagro@hotmail.com; 2. Professors of the Federal University of 
Paraíba, Center for Agrarian Sciences (CCA-UFPB), Brazil; 3. PhD in agronomy, Federal University of Paraíba (CCA-UFPB), Brazil; 

4. Master of the Graduate Program in Plant Science, "Luiz de Queiroz" School of Agriculture, Brazil.  
 

ABSTRACT: The study of plant behavior in environments with different luminous intensities offers 
information about their ability to modify their growth and performance in response to light. The objective of this study was 
to evaluate the influence of shading on the development of Dimorphandra gardneriana Tul. Different levels of shading 
were used, with 0% shading (full sun) - (T1), 30% - (T2), 50% - (T3) and 70% shading - (T4). The different levels of 
shading were obtained by means of black polyolefin screens, sombre type, each treatment consisting of four replicates of 
15 plants. The evaluated characteristics were: number of leaves, plant height, neck diameter, survival percentage, shoot 
length and primary root, green and dry mass of shoots and roots, total dry mass, Dickson quality index and (AP/MSPA), 
shoot height and diameter (A/DC), aerial part and root dry mass (MSPA/MSR), shoot height and dry mass (CPA/CR), as 
well as the percentage of roots (%R). The shading influenced negatively the quality of D. gardneriana  seedlings, being 
those grown in full sun the ones that presented the best quality. Based on the morphological parameters studied, it can be 
affirmed that the D. gardneriana Tul., seedlings, produced in an open environment with high luminosity showed superior 
qualities in relation to the shaded seedlings. 

 
KEYWORDS: Fava d'anta. Forest. light. 

 
INTRODUCTION 

 
The tree species, Dimorphandra 

gardneriana Tul., known as faveira or fava d'anta is 
a legume from the Fabaceae that can reach up to 10 
meters high. It has a panicle inflorescence type, with 
short spikes and yellow flowers. Flowering occurs 
in the rainy season, more precisely in December, 
and fruiting begins in January until August and 
September (RIBEIRO-SILVA et al., 2012). The 
fruit is an indehiscent flat legume, ranging from 
dark brown to almost black in color; it is opaque, 
with a rough, irregular surface with a rounded apex 
and base, and is used for the extraction of rutin, an 
important flavonoid used in the pharmaceutical 
industry (RIBEIRO-SILVA et al., 2007; LANDIM; 
COSTA, 2012). 

Flavonoids are phenolic compounds that 
have roused considerable interest recently because 
of their potential beneficial effects on human health, 
such as a circulatory stimulant, and are, therefore, 
used in mesotherapy or intradermotherapy against 
cellulite (LANDIM; COSTA, 2012). Rutins were 
described by Chen et al. (2013) a natural therapeutic 
drug with the potential for treating neuroblastomas, 
which are malignant neuroblast tumors that occur in 
the adrenal gland and are frequent in children during 
the first year of life. There are also reports that 

flavonoids can prevent prostate cancer (GEYBELS 
et al., 2013). 

Dimorphandra gardneriana is typical of the 
cerrado and caatinga ecosystems of Brazil, and 
occurs naturally in the states of Maranhão, Piauí, 
Ceará, Pernambuco, Bahia, Pará, Goiás, Mato 
Grosso, and Minas Gerais (MONTANO et al., 
2007). Regarding Ceará, the National Araripe Forest 
has great biodiversity, including D. gardneriana 
Tul., which was explored for the extractive form at 
this location (RIBEIRO-SILVA et al., 2012). 

The harvest of fruits for rutin extraction 
reduced seed dispersion, which is a risk to the 
maintenance of species. Therefore, it is important to 
emphasize that the management and conservation of 
the species depends on a better understanding of the 
ecological implications of its fruit extraction 
(RIBEIRO-SILVA, 2007; RIBEIRO-SILVA et al., 
2012). 

Seedling production in nurseries is one of 
the most important phases of the forest stand 
implementation process (COSTA et al., 2008); 
however, the success of a planting depends on the 
quality of seedlings produced, especially the 
morphological and physiological quality, and these 
characteristics are influenced by the seed origin, 
methods used in seedling production, management, 
equipment, nursery structures, as well as the 

Received: 15/08/17 
Accepted: 15/06/18 



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environmental conditions at the site where the 
seedlings are produced (CARON et al., 2010). 

Among the environmental factors that 
directly affects forest seedling production is the 
light requirement of the species, including light 
intensity, quality, and duration, since the availability 
of radiation is an important factor in energy flow in 
biological systems, and depending on the ability to 
capture and use light, the responses of plants are 
different and crucial for their survival, growth, and 
adaptation to different environments (SARAIVA et 
al., 2014; AZEVEDO et al., 2015). With this, Dutra 
et al. (2015) emphasized that changes of growth 
efficiency can be associated with the ability of 
plants to adapt to the environmental light conditions. 

Shading is a technique used to protect plants 
from the harmful rays of the sun, especially during 
periods of high energy availability, as well as 
contributing to ameliorating the plant temperature, 
which may positively affect the growth rate and 
quality of seedlings, as the ecological class of the 
species (CARON et al., 2010). 

The light intensity requirement of different 
species in the initial phase varies, for example, 
Schizolobium parahyba (Vell.) S. F. Blake can be 
produced in shadings of 30%, 50%, and 70%, 
obtaining quality seedlings with stem height and 
diameters compatible for transplanting, but its 
exposure to shade should not exceed 45 days, since 
from that period the plants begin the process of 
blanching (CARON et al., 2010). However, 
Azevedo et al. (2015) found that Azadirachta indica 
A. Juss seedlings produced in full sun had a better 
quality standard based on the morphological 
characteristics, such as stem diameter, 
height/diameter, fresh and dry mass of roots, 
number of leaves, and the Dickson index quality. 

The objective of the present study was to 
evaluate the effect of shading on D. gardneriana 
Tul. seedling development. 
 
MATERIAL AND METHODS 
 

The work was carried out in the forest 
nursery of the Laboratory of Plant Ecology (LEV),  
Department of Plant and Environmental Sciences, 
Center of Agricultural Sciences, Federal University 
of Paraíba in Areia - PB. The seeds were obtained 
from fruits harvested in mother plants located in 
forest remnants near the cities of Jardim (Latitude: 
07º 34' 57" S and Longitude: 39º 17' 53" W ) and 
Crato (Latitude: 07º 14' 03" S and Longitude: 39º 
24' 34" W), Ceará State.  

After harvesting, the fruit was manually 
processed at collection site, and subsequently the 

seeds were placed in plastic bags and transported to 
the Seed Analysis Laboratory  (LAS) where they 
were placed in plastic containers and stored in a 
cold chamber 15 °C for two years, when they were 
used for the experiment. 

To verify the plant requirements for light 
intensity, different levels of shading were used, 
including 0% (full sunlight; T1), 30% (T2), 50% 
(T3), and 70% (T4) shading. These levels were 
evaluated at 30 days after transplanting at 21 day 
intervals. To obtain the different levels of shading, 
the seedlings were placed under wooden frames 
(approximately 1.5 × 1.0 × 1.0 m) that were covered 
on the top and sides with black polyolefin shading-
type screens, and each treatment consisted of four 
replicates of 15 plants. The design used in the 
experiment was completely randomized with four 
replications of 15 plants per treatment. 

Before the experiment was carried out, 
seeds were sown in plastic trays (49 × 33 × 7 cm) 
containing vermiculite, where the seeds after 
overcoming dormancy, by lopping opposite the 
hilum (URSULINO, 2013) were sown at a depth of 
2 cm and kept in the shade for 15 days. 
Subsequently, seedlings were transferred to a 
greenhouse for five days to acclimate, and thereafter 
each plant was transplanted to a polyethylene bag 
(15 × 28 cm). The substratum used was topsoil and 
the plants were kept under different levels of 
shading for 93 days, and during this period the 
humidity of the substrate was maintained by daily 
watering. 
Characteristics evaluated were:  

Number of leaves: recorded from 30 days 
after transplanting at 21 day intervals, counting all 
the leaves present on each plant, up to 93 days after 
transplanting, when the experiment was completed.  

Plant height: determined using a ruler 
graduated in centimeters, measuring from the base 
of the stem to the insertion of the last leaf, from 30 
to 93 days after transplanting at 21 day intervals, 
and the results were expressed in cm/plant. 

Stem diameter: measured at the plant's lap, 
with the aid of a digital caliper rule, from 30 to 93 
days after transplanting, at 21 day intervals, and the 
results were expressed in millimeters. 

The relationship between plant height and 
stem diameter (AP/DC): determined by dividing the 
plant height by the diameter of the lap, from 30 to 
93 days after transplanting at 21 day intervals. 

Percentage survival: analyzed at the end of 
the experiment by recording the number of plants in 
each treatment. 

Shoot and primary root length: at the end of 
the experiment, plants of each treatment were 



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measured (root and shoot) using a ruler graduated in 
centimeters and the results were expressed in plant 
cm-1. 

Shoot and root green mass: after the 
previous measurement plants of each treatment and 
repetition were separated into roots and shoots and 
weighed using an analytical balance accurate to 
0.0001 g and the results were expressed in g per 
plant-1. 

Shoot and root dry mass: after previous 
evaluations, the same plants separated into roots and 
shoots were placed in paper bags and placed in a 
forced ventilation oven at 65 °C for 48 hours. After 
this period, the samples were weighed using an 
analytical balance accurate to 0.0001 g and the 
results expressed in g per plant-1. 

Total dry mass: after the determination of 
the dry mass of roots and shoots, the total dry mass 
was determined by the sum of the dry weight of 
roots and shoots, and the results were expressed in g 
per plant-1. 

Dickson quality index (DQI): determined 
according to the weight of the total dry matter 
(MST), plant height (A), stem diameter (DC), dry 
weight of shoot (MSPA) and root (MSR) by the 
formula of Dickson et al. (1960). 

The ratio between shoot and root dry mass 
(MSPA/MSR): at the end of the experiment, after 
obtaining the above variables, the division between 
the dry mass of shoots and roots was performed. 

Ratio between plant height and shoot dry 
mass (AP/MSPA): obtained by dividing plant height 

and dry weight of shoots, which is considered the 
dry mass of stem and leaves. 

Ratio of length of shoots and primary roots 
(CPA/CR): obtained by dividing the length of the 
shoots and primary roots.  

Percentage of roots (R%): determined by 
dividing the dry root weight by the total dry mass 
and the result multiplied by 100, using the formula: 
% ROOT = MSR/MST × 100. 
 Growth was assessed by height, diameter, 
and leaf number, and treatments were arranged in a 
split plot where the plots were composed of shading 
levels and the subplots were composed of the 
assessments over time. Multiple regression analyses 
were used to analyze the data over time; the data of 
the final evaluation were subjected to polynomial 
regression analysis by testing linear and quadratic 
models. The Pearson correlation was applied to 
verify the relationship between two or more 
variables. 
 
RESULTS AND DISCUSSION 

 
The number of leaves and height of D. 

gardneriana seedlings were influenced by levels of 
shading and evaluation periods (Figure 1A-B), 
observing that at both 30 and 93 days of evaluation, 
the number of leaves was lowest in seedlings grown 
in full shade (70%); however, this variable increased 
with time (Figure 1A). For plant height, it was 
found that the highest values were obtained from 
seedlings raised in 70% shading, and the values 
increased with time (Figure 1B). 

 
 

 

 

 
Figure 1. Number of leaves (A) and height (B) of Dimorphandra gardneriana seedlings produced at different 

levels of shading. 
 

A B 



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The number of leaves of the seedlings 
grown under full sunlight was higher than that for 
shaded plants, but in seedlings exposed to full 
sunlight the leaves and plant height were noticeably 
reduced than those grown in shade. This could be a 
mechanism of species adaptation to low light 
environments, and increased leaf surface area, to 
increase the uptake of light and the photosynthetic 
rate. 

Leaf expansion in low light conditions is a 
frequently reported behavior and indicates how 
plants more effectively utilize low light (LIMA et 
al., 2008) because depending on the skill of capture 
and use of light, the responses of plants are distinct 

and crucial for their survival, growth, and adaptation 
to different environments (SARAIVA et al., 2014). 

Data regarding to the ratio height/diameter 
and stem diameter of D. gardneriana seedlings did 
not fit the multiple polynomial regression models, 
evidencing little variation in height/diameter in the 
treatments and evaluation period. However, these 
values tended to increase with increasing shading, 
where as the diameter demonstrated increasing 
values, but at day 93, similar values were obtained 
for all levels of shading, but there was a higher 
increase in seedling diameters exposed to 30% 
shade and full sun (Table 1). 

 
Table 1. Ratio height/diameter and stem diameter of Dimorphandra gardneriana seedlings produced at 

different levels of shading. 
Níveis de 

sombreamento (%) 
Relação altura/diâmetro Diâmetro do caule (mm) 
Períodos de avaliação Períodos de avaliação 

30 51 72 93 30 51 72 93 
0 4,17 4,22 4,28 4,68 1,5 1,7 2,0 2,5 

30 4,05 4,28 4,71 5,18 1,3 1,5 1,9 2,5 
50 3,65 4,25 4,41 4,88 1,5 1,5 1,8 2,2 
70 5,43 5,46 5,96 7,89 1,2 1,5 1,8 2,1 

 
The highest ratio of height/diameter was 

obtained from seedlings exposed to 70% shading 
and as light availability increased this was reduced, 
which may have been owing to a higher increase in 
the diameter of the exposed plants in higher light 
concentrations. For seedlings of Toona ciliata M. 
Roem var. australis produced without shading, the 
lowest height/diameter was not synonymous of 
quality, because the seedlings grown in full sun 
were necrotic, which had negative influence on the 
increase in height (MARCO et al., 2014). 

Greater increases in height were also 
observed by Freitas et al. (2012) in seedlings of 
Sclerolobium paniculatum Vogel when subjected to 
50% shading than those seedlings grown in full sun. 
However, the maximum height of Copaifera 
langsdorffii Desf. seedlings was achieved with 63% 
shading (DUTRA et al., 2015). 

Seedlings of Ochroma pyramidal (Cav. Ex 
Lam.) were influenced by different shadings, with 
the highest growth (height and diameter) occurring 
under 30% shading achieved using a reflective 
screen of 50% (Santos et al., 2014). In the study by 
Azevedo et al. (2015), using different shading levels 
(0%, 30%, 50%, and 70%) in the production of 
seedlings of Azadirachta indica A. Juss, the highest 
height and diameter values, and lowest 
height/diameter ratios were obtained from seedlings 
produced full sun. 

However, Dipteryx alata Vog. seedlings 
produced in environments with 0%, 30%, 50%, and 
70% shading showed better performance in stem 
diameter than those produced in full sun and 30% 
shading, but the height and leaf number were higher 
for seedlings at 30% shaded (QUEIROZ; 
FIRMINO, 2014). By studying the behavior of 
Schizolobium amazonicum Huber ex Ducke 
seedlings in full sun environment, 75% shade, and 
greenhouse, Frigotto et al. (2015) observed that 
plant height, stem diameter, and number of leaves of 
seedlings grown in full sun were significantly lower 
than that of the other treatments. 

Therefore, it is evident that the plant 
performance in relation to light is varied, and 
different species behave differently when subjected 
to different environments, which makes it important 
to determine the behavior of various species when 
exposed to different light intensities. 

For the length of the primary root and DQI 
of D. gardneriana seedlings, the linear regression 
mode indicated significant reductions with increased 
shading levels, whereas the shoot length and 
percentage survival did not fit the polynomial 
regression models, with mean values of 13.59 cm 
and 91%, respectively (Figure 2A-D). 

The length of the primary root was 
negatively affected by shading levels, with the 
highest values observed in seedlings grown in full 



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sun, possibly owing to the need for greater water 
absorption owing to the high evapotranspiration 
rate, which is in accordance with the studies of Lei 
and Lechowicz (1998) and Poorter (1999), who 
reported this as functionally accurate: owing to the 

greater evapotranspiration demand, increased 
investment in dense root system growth assumes 
greater importance in plants under conditions of 
high irradiance than those in shaded environments.

  

 
 

 

Figure 2. Length of the primary root (A), the shoot (B), Dickson quality index (C) and survival percentage (D) 
of Dimorphandra gardneriana seedlings produced at different levels of shading. 

 
Therefore, Gomes and Paiva (2013) argued 

that good root development can ensure better 
performance in the field, given that they are closely 
related to the physiological activities of plants in 
complex soil-water-plant environments. For 
Ochroma pyramidal (Cav. Ex Lam.) Urb. seedlings, 
the difference in shading environments (shading 
30% and 50%, open field, term reflector 30% and 
50%) did not affect the length of the primary root 
(SANTOS et al., 2014), whereas for length of the 
primary root of Dipteryx alata Vog seedlings it was 
highest in 50% and 70% shade than that of other 
shading levels (0–30%) (QUEIROZ and FIRMINO, 
2014). 

The shoot length data did not fit the 
regression models, but there was a growing trend at 
the highest level of shading (Figure 2). According to 
Marco et al. (2014) shaded plants tend to have 
greater height owing to light deficiency and 
therefore blanching occurs. The percentage of D. 
gardneriana seedling survival was not influenced by 
levels of shading used in nursery, with high 
percentages in all treatments. 

For seedlings of Copaifera langsdorffii 
Desf., the 50% shading level showed a higher 

survival percentage (DUTRA et al., 2015), whereas 
Schizolobium amazonicum Huber ex Ducke 
seedlings produced in open fields had only a 42% 
survival, which was attributed to the presence of 
frost in the region (FRIGOTTO et al., 2015). 

Dimorphandra gardneriana seedlings 
produced in full sun showed higher a DQI, and may 
be considered better quality than the shaded 
seedlings, since other important variables, such as 
height, diameter and dry mass of roots and shoots 
was taken into account. According to Fonseca et al. 
(2002), DQI is a good indicator of seedling quality 
because changes in the strength and balance of the 
distribution of biomass are assessed, and several 
important parameters are used to assess the quality. 

The DQI of Sclelorobium paniculatum 
seedlings grown under different levels of shading 
(natural shade, 50% shade, and full sun) was 
significantly different from that of seedlings grown 
in full sun, which exhibited better quality than those 
grown in shade (FREITAS et al., 2012). For Toona 
ciliata var. australis, seedlings the best DQI was 
achieved when a simple shading layer was used 
(MARCO et al., 2014). 

A B 

C 
D 



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The different levels of shading (0%, 30%, 
50%, and 70%) influenced the quality of 
Azadirachta indica seedlings, with the highest DQI 
values obtained from seedlings grown in full sun 
(AZEVEDO et al., 2015). The DQI was also 
considered by Dutra et al. (2015) as an excellent 
variable to indicate the standard of seedling quality 
of Copaifera langsdorffii Desf., since the seedlings 
with the highest rates had  maximum total dry mass 
and shoot values. 

The data of green and dry mass of roots and 
shoots, as well as the total dry mass of D. 
gardneriana seedlings fit the linear regression 
model, with significant reductions in terms of 
shading levels (Figure 3A-E). This emphasized that 
seedlings grown in full sun had a higher content of 
green mass, dry and total mass, whereas the masses 
from seedlings produced in 70% shading were lower 
because the total dry mass decreased from 1.28 
(zero shading) to 0.70 g (70% shading). 

  

  

 

 

 

Figure 3. Green root mass (A), green shoot mass (B), dry roots mass (C), dry shoot mass (D) and total dry 
mass (E) of Dimorphandra gardneriana seedlings produced at different levels of shading. 

 
 
In 70% shade, only 30% light was available 

for the plants, which may have contributed to the 
lower content of fresh and dry mass since the 
reduction in light availability causes a decrease in 

photosynthetic rate, and according to Floss (2004), a 
plant exposed to the sun can photosynthesize almost 
three times more than a shaded plant. Therefore, 
light availability is a key factor in the flow of energy 
in biological systems and is crucial for the 

A B 

C D 

E 



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physiological processes of plants (SARAIVA et al., 
2014). 

Among the morphological characteristics 
that determine seedling quality, the dry matter 
content has been considered one of the best because 
the survival and early growth are related to it 
(GOMES; PAIVA, 2013). In this study, it was 
found that seedlings grown in full sun were the most 
productive since the biomass was considerably 
higher than that of seedlings grown in shaded 
treatments. 

Light has a considerable influence on 
several morphological, anatomical, and 
physiological plant characteristics, and the leaves of 
plants growing in full sun have more chloroplasts, a 
higher chlorophyll content, greater leaf thickness, 
which explains why plants growing in high light 
conditions are more efficient (FLOSS, 2004). In this 
context, Santos et al. (2013) stated that brightness 
controls the processes responsible for the 
accumulation of dry mass, contributing to seedling 
growth. 

The dry weight of leaves, stems, and roots, 
as well as the total dry mass of Caesalpinia ferrea 
Mart. ex. Tul. seedlings were higher when produced 
in full sun than those produced in shades of 50% 
and 70% shade (LIMA et al., 2008). For 
Schizolobium parahyba (Vell.) seedlings, Caron et 
al. (2010) found that shading levels of 0%, 30%, 
50%, and 70% did not affect the dry matter 
accumulation in different parts of the plant. 

The quality of Ochroma pyramidal (Cav. Ex 
Lam.) seedlings was influenced by the tested 
shading (30% and 50%), which had a positive effect 
on plant growth, and resulted in the highest fresh 
and dry mass content of shoots and root s( SANTOS 
et al., 2014). The dry weight of shoots and roots of 
Dipteryx alata Vog. seedlings was higher in 70% 
shading, with 3.37 and 2.47 g, respectively, 
compared to that of other shading levels (0–30%), 
and the authors attributed these results to the larger 
number of leaves and higher root length obtained 
with this shading (QUEIROZ and FIRMINO, 2014). 

For the relationship between the dry 
weight of shoots and roots, plant height and dry 
weight of shoot, shoot length and primary root a 
linear model was fitted, which increased with 
increasing shading levels (Figure 4A-C). However, 
the percentage of roots decreased linearly with 
increasing shading levels (Figure 4D). 

The lowest evaluated relations were 
observed in seedlings grown in full sun, indicating 
that these are of superior quality, since the 
relationship between the dry weight of shoots and 
roots is an important variable in determining the 

quality of seedlings, and established the value of 
2.0 as the best relationship between these two 
factors, whereas the relationship between plant 
height and weight of shoot can predict the 
potential for survival in the field, so that the lower 
this is more resistant index is the changes and 
increased its survivability (GOMES; PAIVA, 
2013). 

In plant growth, there is an interdependence 
between the functioning of the root system and 
shoot, for example, in seedlings grown in full sun 
there was a lower ratio between the length of shoots 
and primary roots owing to the higher growth of the 
primary root; however, in shaded seedlings the 
development of more shoots was prioritized, and so 
a greater relationship between these two structures 
occurred. 

This can be corroborated with the results of 
the percentage of roots where the lowest values 
occurred in the shaded plants (Figure 4D), and 
according to Fonseca et al. (2002), morphological 
characteristics and relationships used to evaluate 
seedling quality should not be used alone to reduce 
the risk of selecting seedlings with higher root 
percentages, although they are weak, or discarding 
smaller yet more powerful seedlings. 

In a study by Freitas et al. (2012), 
Sclelorobium paniculatum Vog. seedlings grown in 
different conditions (natural shade, 50% shade, and 
full sun) had a lower shoot/root ratio under full sun, 
possibly because the plants grown in high light 
intensities had a higher allocation of assimilates to 
the roots. In Caesalpinia ferrea Mart. Ex Tul., 
seedlings produced in full sun, Santos et al. (2013) 
found a lower ratio of the dry mass of shoots and 
roots. 

It was found that there was no significant 
Pearson correlation between the length of shoots 
and green mass of roots and dried mass of roots, the 
total dry mass, and primary root length, but these 
variables are correlated significantly positively 
among them; however, there was a significant 
negative correlation between shoot length and green 
mass shoots and dry mass of shoots, indicating that 
the increase implies a decrease in the other (Table 
2). 

The DQI is strongly correlated with all 
variables, except for the length of shoots, but the 
correlation of DQI with the ratios of dry mass of 
shoots and roots, height plant, and dry weight of 
shoot, shoot length and primary ratio was significant 
and negative. However, these same ratios were 
correlated significantly and negatively with the mass 
of roots and root length, but significantly and 
positively with the shoot length (Table 2). 



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Figure 4. Ratio between the dry mass of shoots and roots (MSPA/MSR) - (A), plant height and weight of 
shoot (AP/MSPA) - (B), length of shoot and primary root (CPA/CR) - (C) and percentage of roots 
(% R) - (D) of Dimorphandra gardneriana seedlings produced at different levels of shading. 

 
Table 2. Pearson correlation coefficients between the green mass of shoots (MVPA) and roots (MVR), dry 

mass of roots (MSR) and shoots (MSPA), total dry mass (MST), length of primary root (CR) and 
shoot (CPA), Dickson quality index (DQI), ratio of the dry mass of shoots and roots (MSPA/MSR), 
plant height and dry mass of shoots (AP/MSPA), length of shoot and primary root (CPA/CR) and 
percentage of roots (% R) of Dimorphandra gardneriana seedlings. 

 

** significant at 1%, * significant at 5% probability. nsNot significant. 
 

Variables MVPA MSR MSPA MST CPR CPA IQD MSPA/MSR APA/MSPA CPA/CR %R  

MVR 0,65* 0,88** 0,62** 0,73** 0,80** -0,31ns 0,87** -0,79** -0,87** -0,64** 0,87**  

MVPA - 0,65** 0,86** 0,83** 0,54* -0,76** 0,57* -0,79** -0,74** -0,82** 0,80**  

MSR - - 0,80** 0,88** 0,86** -0,21ns 0,98** -0,81** -0,90** -0,60** 0,90**  

MSPA - - - 0,98** 0,64* -0,47* 0,74** -0,73** -0,73** -0,63** 0,79**  

MST - - - - 0,72** -0,40ns 0,83** -0,75** -0,80** -0,63** 0,83**  

CPR - - - -  -0,24ns 0,89** -0,66** -0,85** -0,68** 0,74**  

CPA - - - - - - -0,12ns 0,58* 0,51* 0,86** -0,53*  

IQD - - - - - - - -0,76** -0,86** -0,53* 0,85**  

MSPA/MSR - - - - - - - - 0,82** 0,78** -0,97**  

APA/MSPA - - - - - - - - - 0,81** -0,89*  

CPA/CR - - - - - - - - - - -0,77**  

% R - - - - - - - - - - 1  

A B 

C D 



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The percentage of roots was correlated 
significantly and negatively with the length of the 
shoot and ratios of dry weight of shoots and roots, 
plant height and dry weight of shoots, and shoot 
length and primary root, however, this correlation 
with other variables was significant and positive, 
whereas the survival rate did not correlate with any 
of the variables evaluated (Table 2). 

The presence of a significant negative 
correlation between variables indicated that there is 
inversely proportional behavior between them, or as 
one increased the other decreased, such as the 
significant negative correlation between the length 
of shoots and green and dry mass shoots, since the 
greater height did not correspond to the maximum 
green and dry mass content. However, the positive 
and significant correlation indicated that the 
increase of one implies the gain of the other, 
emphasizing the DQI, which together with the green 
and dry mass of roots and shoots and total dry mass, 
as well as the primary root length are important 
variables in determining the quality of D. 
gardneriana seedlings. 

The seedlings of D. gardneriana produced 
in full sun showed superior characteristics to those 
produced in the shade, indicating greater 
adaptability to high light conditions. In this sense, 
Freitas et al. (2012) point out that the greater 

adaptability of the species to the high incidence of 
light could ensure the success of a degraded area 
recovery project, and pioneer and early secondary 
species are recommended to start the successional 
stages in recovery projects of degraded areas, owing 
to their adaptation to most light conditions. 

Therefore, it should be emphasized that 
knowledge of potential use, physiology, 
management and seedling production can contribute 
both to the maintenance of forests and planning the 
environmental restoration of the original vegetation 
(ALMEIDA et al., 2005). Many native species are 
potentially suitable for rational cultivation and can 
be used for several purposes, including ornamental, 
wood, food, medicinal, and preservation. 
 
CONCLUSIONS 

 
Seedlings produced in full sun had higher 

values of the characteristics (number of leaves, root 
length, green and dry mass of root and shoot and 
total, DQI, and highest percentage of root) than 
those produced in shade.  

Based on the morphological parameters 
studied, it can be affirmed that the D. gardneriana 
Tul., seedlings, produced in an open environment 
with high luminosity showed superior qualities in 
relation to the shaded seedlings. 

 

 
RESUMO: O estudo do comportamento de plantas em ambientes com diferentes intensidades luminosas oferece 

informações sobre a capacidade que elas têm em modificar seu crescimento e desempenho em resposta à luminosidade. 
Assim, objetivou-se avaliar a influência do sombreamento no desenvolvimento das mudas de Dimorphandra gardneriana 
Tul. Foram utilizados diferentes níveis de sombreamentos, sendo estes compostos por 0% de sombreamento (pleno sol) - 
(T1), 30% - (T2), 50% - (T3) e 70% de sombreamento - (T4). A obtenção dos diferentes níveis de sombreamento foi por 
meio de telas de poliolefinas de cor preta, tipo sombrite, sendo cada tratamento composto por quatro repetições de 15 
plantas. As características avaliadas foram: o número de folhas, altura da planta, diâmetro do colo, porcentagem de 
sobrevivência, comprimento de parte aérea e raiz primária, massa verde e seca da parte aérea e raízes, massa seca total, 
índice de qualidade de Dickson e a relação entre altura e diâmetro do colo (A/DC), massa seca da parte aérea e das raízes 
(MSPA/MSR), altura de planta e massa seca da parte aérea (AP/MSPA), comprimento da parte aérea e da raiz primária 
(CPA/CR), assim como a porcentagem de raízes (%R). O sombreamento influenciou negativamente a qualidade das mudas 
de D. gardneriana, sendo aquelas cultivadas a pleno sol as que apresentaram melhor qualidade. Com base nos parâmetros 
morfológicos estudados, pode-se afirmar que as mudas de D. gardneriana Tul., Produzidas em ambiente aberto com alta 
luminosidade, apresentaram qualidades superiores em relação às plântulas sombreadas. 

 
PALAVRAS-CHAVE: Fava d’anta. Espécie florestal. Luminosidade. 

 
 

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