Microsoft Word - 2-Agra_41791


1090 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1090-1098, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-41791 

PRE-GERMINATION TREATMENTS OF PARICÁ (Schizolobium amazonicum) 
SEEDS 

 
TRATAMENTOS PRÉ-GERMINATIVOS EM SEMENTES DE PARICÁ (Schizolobium 

amazonicum) 
 

Estefânia Martins BARDIVIESSO1; Thiago Barbosa BATISTA1;  
Flávio Ferreira da Silva BINOTTI2; Edilson COSTA2; Tiago Alexandre da SILVA1;  

Natália de Brito Lima LANNA1; Ana Carolina Picinini PETRONILIO1 
1. Paulista State University “Júlio de Mesquita Filho” – College of Agricultural Science, Department of Crop Science, Botucatu, SP, 

Brazil. estefania.bardiviesso@hotmail.com; 2. Mato Grosso do Sul State University, Cassilândia, MS, Brazil. 
 

ABSTRACT: Paricá seeds have dormancy and, even after mechanical scarification, these seeds show 
slow and uneven germination. Pre-germination treatments can be used to increase seed germination 
performance. Thus, the aimed to evaluate the physiological potential and initial growth of paricá seeds after 
pre-germination treatments, using different substances as plant regulators and nutrients, in addition to 
mechanical scarification. The experimental design was completely randomized, in a 2x7 factorial scheme, 
consisting of the following pre-germination treatments: mechanical scarification (10% and 50% of the seed 
coat) and seed pre-soaking [control-water, KNO3 0.2%, Ca(NO3)2 0.2%, gibberellin 0.02%, cytokinin 0.02%, 
and mixture of gibberellin + cytokinin (1:1)] besides a control group without pre-soaking, with four replicates. 
The study evaluated germination and emergence rates, germination and emergence speed indices, collar 
diameter, plant height, seedling dry mass, hypocotyl and seedling length, and electrical conductivity. It was 
observed that pre-soaking the seeds in gibberellin after mechanical scarification at 50% as a pre-germination 
treatment resulted in seeds with higher vigor expression and greater initial seedling growth. 
 

KEYWORDS: Gibberellin. Cytokinin. Pre-soaking. Mechanical scarification. 
 
INTRODUCTION 

 
Schizolobium amazonicum (Huber ex 

Ducke) Barneby, the Brazilian fern tree, locally 
referred to as paricá, is a forest species of the family 
Fabaceae (Leguminosae) and subfamily 
Caesalpinoideae (BARNEBY, 1996). The species 
has a wide geographical distribution, can be found 
in the Brazilian states of Amazonas, Pará, Mato 
Grosso and Rondônia and is indicated for 
commercial crops, agroforestry systems and 
reforestation of degraded areas owing to its rapid 
growth and high commercial value (TAVARES et 
al., 2013). 

The species is propagated by seeds, and 
seedling production in commercial nurseries 
depends on factors such as collection, storage and 
the overcoming of seed dormancy, which can affect 
seed germination or seedling formation (NEVES; 
DALCHIAVON; STIELER, 2010). 

In nature, paricá seeds have slow and 
reduced germination, but when subjected to 
scarification, germination rates rise above 90% 
(CRUZ; CARVALHO, 2006; CARVALHO, 2007). 
This prolonged time to germination is a strong 
evidence that the seeds of this species are affected 
by physical or integument dormancy capable of 

limiting the rapid and uniform germination of the 
seeds (CRUZ; MARTINS; CARVALHO, 2001). In 
intact seeds of this species, hydration does not occur 
even after they are immersed in water for 72 hours 
(SHIMIZU et al., 2011). Such dormancy, caused by 
restricted water entry, is typical of the family 
Leguminosae (PEREZ, 2004), and since they have 
dehiscent fruits, their seeds have lignified 
integument thus granting them greater protection 
(DAMIÃO FILHO; MORO, 2005). 

Several methods have been developed to 
overcome seed dormancy of forest species, such as 
mechanical and chemical scarification (ALVES et 
al., 2008). Studies on seeds of S. amazonicum 
(CRUZ; CARVALHO, 2006) and seeds of Zizyphus 
joazeiro (ALVES et al., 2008) showed that 
mechanical scarification with sandpaper is efficient 
for overcoming physical dormancy. In effect, such 
scarification methods influence the establishment of 
seedlings and saplings. 

Pre-soaking treatments can also help the 
seeds to express their full physiological potential, 
especially by the use of plant and/or nutrient 
regulators, which can be used as a pre-germination 
treatment, contributing to germination (PRADO 
NETO et al., 2007; CANESIN et al., 2012). The use 
of plant regulators can beneficially influence the 

Received: 08/04/19 
Accepted: 20/12/19 



1091 
Pre-germination …  BARDIVIESSO, E. M. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1090-1098, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-41791 

germination process, allowing germination speed 
and uniformity, besides favoring plant growth. 
Thus, the aim of this study was to evaluate the effect 
different intensities of mechanical scarification and 
pre-soaking treatments with different chemical 
agents in paricá seeds. 

 
MATERIAL AND METHODS 
 

Paricá seeds were collected from matrices in 
the region of Paragominas (Pará-Brazil) with a 
germination rate equivalent to zero prior to the 
experiment onset. The experimental design was 
completely randomized in a 2 x 7 factorial scheme, 
consisting of mechanical scarification (10% or 50% 
of integument fragmentation) and seed pre-soaking 
with different chemical agents [, control-water, 
KNO3 0.2%, Ca(NO3)2 0.2%,  0.02% gibberellin, 
0.02% cytokinin, and mixture of gibberellin + 
cytokinin (1:1)] besides a control group without pre-
soaking, with four replicates. 

For seed mechanical scarification, an 
electric sander was used in the opposite direction of 
the embryonic axis, removing part of the integument 
(10% or 50% of integument fragmentation). For the 
10% scarification, the integument was removed 
from the lateral upper part of the seeds opposite to 
the micropyle, and for the 50% scarification, the 
integument was removed from one of the lateral 
ends of the seeds. 

Seeds were pre-soaked in deionized water; 
potassium nitrate - KNO3 0.2%; calcium nitrate - 
Ca(NO3)2 0,2%; gibberellin - GA3 0,02%; cytokinin-
6-benzylamino-purine 0.02%; and mixture of 
gibberellin + cytokinin (1:1). The pre-soaking 
period was selected according to the absorption 
curve in deionized water, establishing the period of 
hydration prior to radicle protrusion, which for 
10%-scarified seeds was 27 hours and for 50%-
scarified seeds, 23 hours. 

Seed physiological potential and seedling 
performance after the pre-germination treatments 
were evaluated by the methods described below: 

Germination rate: performed with 4 
replicates of 25 seeds, seeded on paper rolls 
moistened with deionized water in the ratio of 2.5 
times the substrate mass. The paper rolls were put in 
plastic bags and then placed in a room seed 
germinator at 25 °C, and photoperiod of 12 hours. 
The seeds were counted 15 days after experiment 
onset, considering as germinated the seeds with a 
radicle ≥ 2 mm (RAMOS; VARELA; MELO, 
2006). 

Germination speed index: performed in 
conjunction with the germination test, with daily 

counts of the germinated seeds (15 days), calculated 
according to the formula below, adapted from 
Maguire (1962): GSI = (G1/N1 + G2/N2 + ...+ 
Gn/Nn), where: GSI = germination speed index; G1, 
G2 e Gn = number of seeds with radicle protrusion 
determined at the first, second ...and last count; N1, 
N2 e Nn = number of days from the experiment onset 
until the first, second ...and last count. 

Electrical conductivity: performed by 
means of the test known as "mass conductivity", 
with 4 replicates of 10 seeds. For each replicate, 
seed mass was measured with precision of at least 
three decimal places, then seed was soaked in a 
container with 75 mL of deionized water (3-5 μS 
cm-1 of conductivity), and kept in a room seed 
germinator at 25 °C for 24 hours. After the 24 hour 
period, the electrical conductivity in the soaking 
solution was measured using a benchtop 
conductivity meter. The results were expressed in 
μS cm-1 g-1 of seeds (VIEIRA; KRZYZANOWSKI, 
1999). 

Hypocotyl length: performed in the 
laboratory with 4 replicates of 12 seeds, on 
germination paper, along two longitudinal lines 
drawn in the upper third of the paper. The seeds 
were positioned in a way that the micropyle faced 
the bottom of the paper. The paper rolls were kept at 
a constant temperature of 25 °C in an upright 
position. After 7 days from experiment onset, 
hypocotyl length was measured (NAKAGAWA, 
1999). 

Seedling emergence rate: performed in a 
greenhouse, using 4 replicates of 25 seeds per 
treatment, sown at 3 cm deep in trays with sand. 
Emerged seedlings were counted after 15 days, 
considering as emerged those with apparent 
hypocotyl above soil surface. 

Emergence speed index: performed in 
parallel with the seedling emergence test. The 
evaluations were performed by counting the number 
of emerged seedlings (after 15 days) daily. The 
emergence speed index was calculated according to 
Maguire (1962) previously described. 

Collar diameter, plant height and dry 
mass: after the seedling emergence test, the plants 
were measured for collar diameter using a digital 
caliper, shoot height (from base to apex) using a 
ruler in centimeter, and seedling dry mass. 
Additionally, remnants of the seeds that were 
adhered to the plants were removed. Subsequently, 
the plants were kept I n a greenhouse with forced air 
circulation at 65 °C for 72 hours. The result was 
expressed in mg plant-1. 

The data were evaluated through analysis of 
variance by the F-test for mechanical scarification, 



1092 
Pre-germination …  BARDIVIESSO, E. M. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1090-1098, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-41791 

and by the Tukey test for the pre-soaking factor, at a 
0.05 significance level (BANZATTO; KRONKA, 
2013). 

 
RESULTS AND DISCUSSION 

Interaction between the studied factors was 
verified for total germination rate, seedling 
emergence rate, germination speed index and 
emergence speed index (Table 1). 

 
Table 1. Effect of the pre-germination treatment on germination (G), germination speed index (GSI), seedling 

emergence (SE) and emergence speed index (ESI) of S. amazonicum. 

Pre-germination treatment 
Mechanical Scarification 
10 % 50% 10 % 50% 10 % 50% 10 % 50% 
G (%) GSI SE (%) ESI 

Non-soaked – Control 92 aB 100 aA 6.17Bb 9.12 dA 98 aA 98 aA 2.30 bB 2.74 bcA 
         
Water 98 aA 95 aA 21.43 aA 22.62 aA 95 aA 95 aA 2.54 abB 3.17 abcA 
         
Gibberellin 93 aA 92 aA 21.20 aA 22.29 aA 96 aA 98 aA 2.89 aB 3.27 abA 
         
Cytokinin 96 aA 76 bB 19.40 aA 12.62 cB 19 cB 38 bA 0.34 dB 0.94 dA 
         
Giberelin + Cytokinin 95 aA 91 aA 20.01 aA 18.66 bA 75 bA 50 bB 1.55 cA 1.10 dB 
         
Potassium Nitrate 99 aA 95 aA 20.25 aB 22.54 aA 96 aA 88 aA 3.07 aA 2.68 cB 
         
Calcium Nitrate 96 aA 98 aA 21.41 aA 22.95aA 89 aA 98 aA 2.16 bB 3.40 aA 
CV % 4.57 6.85 9,81 10.94 
Means followed by different lowercase letters within a column and different uppercase letters within a row differ statistically from each 
other by the Tukey test and by the F-test at a 0.05 significance level, respectively. CV = coefficient of variation. 

 
Germination rate did not differ statistically 

between the pre-germination treatments of the 10%-
scarified seeds. In the non-soaked seeds (control 
group), the 50%-scarification of seed coat resulted 
in higher germination. Cytokinin as a pre-soaking 
chemical agent interfered negatively in germination 
when applied to the 50%-scarified seeds (Table 1). 

Mechanical scarification with emery paper 
on seeds of S. amazonicum resulted in overcoming 
dormancy with increased germination rates (CRUZ; 
CARVALHO, 2006), similar to chemical 
scarification using sulfuric acid (H2SO4) for 60 
minutes (CRUZ; CARVALHO; QUEIROZ, 2007). 
The present study verified that the germination rate 
of S. amazonicum seeds increased as the 
scarification intensity increased, evidencing the 
need for seed coat scarification, as can be seen in 
the literature. This increase in the percentage (50%) 
of integument scarification allowed better hydration 
of the seed tissues, also facilitating radicle 
protrusion, which resulted in an increase in the seed 
germination rate and seedling emergence speed 
(Table 1). This improvement in germination, with 
scarification at a higher intensity, is in line with the 
findings of Santos et al. (2004), who recommended 
coat scarification on both sides of chichá (Sterculia 

foetida L.) seeds, without pre-soaking, to overcome 
dormancy. 

In 50%-scarified seeds, the highest speed 
germination indices were verified in pre-soaking 
treatments using water, gibberellin, potassium 
nitrate and calcium nitrate. In 10%-scarified seeds 
this index was increased with all the chemical 
agents used for pre-soaking (Table 1). 

The increase in the paricá germination speed 
using the chemical agent gibberellin is in agreement 
with the results of Guimarães et al. (2010) in seeds 
of Thlaspi caerulescens, because gibberellin is 
involved in the synthesis of enzymes that degrade 
the reserves of the seed that will be mobilized to the 
embryonic axis to initiate the activity in the root 
apical meristem for its growth, thus allowing radicle 
protrusion. Other positive effects on germination 
from the application of this plant regulator have 
been reported, such as the increase in germination 
rate and speed index in kiwi seeds [Actinidia 
deliciosa (A. Chev.) E. F. Liang et A.R. Ferguson] 
(YNOUE; ONO; MARCHI, 1999), pomegranate 
seeds (Punica granatum L.) (TAKATA et al., 2014) 
and biribá seeds [Annona (Rollinia) mucosa Jacq. 
Baill.] (CAMPOS et al., 2015). 

In paricá seeds, the gibberellin used for pre-
soaking (GA3) did not influence germination rate, 



1093 
Pre-germination …  BARDIVIESSO, E. M. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1090-1098, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-41791 

however it increased the germination speed index. It 
can be inferred that the use of GA3 in pre-soaking 
accelerated the events that trigger the rupture of the 
reserve tissue, leading to a faster growth of the 
embryo axis, which is an advantage for these seeds 
and results in an increase in the germination speed 
index. 

Shimizu et al. (2011) emphasize that 
germination depends mainly on tissue hydration, as 
it promotes resumption of the seed metabolism. The 
mechanical scarification at 50% intensity 
contributed to rapid germination and seedling 
emergence due to greater availability of water for 
the paricá seed tissues, resulting in rapid seed 
soaking. This accelerates the onset of hydrolytic 
enzyme activities and the respiratory process for 
energy production in the form of ATP and carbon 
skeletons required for the other biochemical 
processes that occur during the germination process, 
considering that the intact integument of this species 
prevents the entry of water. 

Pre-germination treatments and scarification 
intensities did not differ statistically for the total 
emergence rates of the seedlings, except for 
treatments with cytokinins (cytokinin, and 
gibberellin + cytokinin), for both 10% and 50% 
scarification intensities, which resulted in a decrease 
in the seedling emergence rate. Additionally, in 
treatments with cytokinin, a negative effect was 
observed for the variables of total germination rate, 
germination speed index and emergence speed 
index. 

Cytokinins are involved in the germination 
process of some species, and may be related to 
membrane permeability (VIEIRA; CASTRO, 2001). 
However, in the present study, the results affected 
all variables and can be explained by the high 
concentration of the commercial product used. It is 
very likely that such high concentration caused 
physiological disturbances during germination, 
impairing even seedling formation (Table 2). 

The 50% scarification combined with the 
calcium nitrate pre-soaking treatment, as well as the 
10% scarification combined with potassium nitrate, 
which did not differ from water and GA3 treatments, 
favored a higher ESI (Table 1). Higher expression 
of seed vigor facilitated emergence (SHIMIZU et 
al., 2011) through mechanical scarification 
associated with chemical agents. Similar results 
were also reported by Lopes et al. (2009) for embu 
seeds (Spondias tuberosa Arruda), Santarém and 

Aquila (1995) for pau-fava seeds [Senna 
macranthera (DC. ex Collad.) H. S. Irwin Barneby], 
Oliveira et al. (2008) for fava d'anta seeds 
(Dimorphandra mollis Benth) and Melo et al. 
(2011) for faveira seeds (Parkia spp).  

Dutra et al. (2012) state that the higher the 
emergence speed, the shorter the time the seeds will 
be exposed to adverse conditions such as pests and 
diseases, in addition to reducing the seedling 
permanence time in nurseries. Therefore, pre-
germination treatments, as those carried out in this 
study, allow obtaining higher-quality seedlings in a 
shorter period of time. 

Seeds pre-soaked with calcium nitrate 
submitted to 50% scarification yielded positive 
values of seed germination rate, GSI, ESI and 
seedling emergence rate (Table 1). Calcium has a 
role in cell division and elongation, and this 
function may explain the effects on the 
physiological quality of the seeds and the initial 
growth of the seedlings described in this study. 

Interaction between the factors studied were 
observed for hypocotyl length, plant height and 
seedling dry mass. The use of gibberellin in seed 
pre-soaking yielded seedlings with higher hypocotyl 
length and plant height, regardless of scarification. 
Gibberellin also promoted higher plant height 
combined with 50% scarification (Table 2), similar 
to the results of Campos et al. (2015) for biribá 
seeds [Annona (Rollinia) mucosa Jacq. Baill.]; and 
contrary to the findings of Takata et al. (2014) using 
gibberellin in the pre-germination treatment of 
pomegranate seeds (Punica granatum L.). 

In line with the results verified in the 
present study, Prado Neto et al. (2007), studying 
different concentrations of gibberellic acid and 
commercial plant stimulant in genipap seeds 
(Genipa americana) through pre-soaking processes, 
found that the presence of gibberellic acid yielded 
seedlings with larger root and shoot length. 

The highest plant growth (with gibberellin) 
(Table 2) observed was due to the fact that 
gibberellin stimulates cell division and elongation, 
favoring the formation of new cells. The GA3 
bioregulator used in this study, and as per Stenzel, 
Murata and Neves (2003), provides stimuli for the 
synthesis of enzymes, which will digest reserves of 
the reserve tissue of the seed, resulting in amino 
acids, nucleic acids and simple sugars, which will be 
absorbed for the growth of the embryo. 

 
 
 
 



1094 
Pre-germination …  BARDIVIESSO, E. M. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1090-1098, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-41791 

Table 2. Effect of the pre-germination treatment on hypocotyl length (HL), plant height (P.H.) and seedling dry 
mass (SDM) of S. amazonicum. 

Pre-germination treatment 
Mechanical Scarification 
10 % 50% 10% 50% 10% 50% 
HL (cm) PH (cm) SDM (mg plant-1) 

Non-soaked – Control 3.31 dB 4.30 cA 25.30 cA 25.64 bA 204,69 bA 222,13 cA 
       
Water  5.75 bA 5.60 bA 27.25 bcA 26.22 bA 234,90 aA 241,62 bcA 
       
Gibberellin 7.55 aA 7.59 aA 32.92 aB 35.27 aA 262,53 aA 279,59 aA 
       
Cytokinin 1.34 eA 1.10 dA 10.56 dA 6.85 dB 169,30 cA 174,39 dA 
       
Giberelin + Cytokinin 1.93 eB 3.43 cA 11.71 dA 10.17 cA 169,63 cA 145,42 Db 
       
Potassium Nitrate 4.51 cB 5.69 bA 27.03 bcA 25.87 bA 251,17 aA 230,99 bcB 
       
Calcium Nitrate 4.40 cB 5.64 bA 28.30 Ba 26.80 bA 241,33 aA 256,63 abA 
CV % 9.84 4.75 6.17 
Means followed by different lowercase letters within a column and different uppercase letters within a row differ statistically from each 
other by the Tukey test and by the F-test at a 0.05 significance level, respectively. CV = coefficient of variation. 

 
The hypocotyl is extremely necessary for 

dicotyledons, mainly because it elevates the 
cotyledons and epicotyl to the soil surface. It is 
associated with the seedling ability to emerge and 
overcome the seeding depth barrier and the soil 
layer. Therefore, when using gibberellin in the pre-
soaking treatment, the seedlings showed greater 
emergence capacity, which can be confirmed by the 
ESI data (Table 1), showing that the use of GA3 in 
the pre-germination treatment increased the speed 
emergence index of the paricá seeds. 

Seed pre-soaking, except for agents 
cytokinin and gibberellin + cytokinin, increased the 
dry mass of the paricá seedlings originated from 
10%-scarified seeds. The highest mass values of 
seedlings originating from 50%-scarified seeds were 
observed for treatments with gibberellin and with 
calcium nitrate (Table 2). The use of cytokinin in 
seed hydration altered the hormonal balance, 
negatively interfering with the physiological 
processes during germination and plant growth 
(evidenced by hypocotyl length, plant height and 
dry mass). According to Vieira et al. (2010), 
cytokinins may promote or inhibit root growth, 
depending on the plant and the concentration; and 
high concentrations may inhibit dry mass growth 
and root elongation. 

Separate influence from the factors studied 
was observed for electrical conductivity and plant 
collar diameter. Higher leaching levels, measured by 
electrical conductivity, were observed for 10%-
scarified seeds (Table 3). 

The use of pre-germination treatments led to 
a reduction in the leaching values, as measured by 
the electrical conductivity test. Water, gibberellin, 
cytokinin and gibberellin + cytokinin obtained lower 
conductivity because seed hydration led to damage 
repair and membrane organization, leaving them 
more selective and thus reducing the amount of 
exudates removed during the process of seed 
soaking.  

The different intensities of scarification did 
not statistically influence plant collar diameter, with 
greater response observed for the pre-germination 
treatment with cytokinin (Table 3). 

The use of cytokinin as a pre-germination 
treatment had a negative influence on seed 
germination, seedling height and emergence, as 
lower results were found in comparison to other pre-
germination treatments (Table 1 and 2). This result 
can be explained by the morphological change 
occurring in the hypocotyl region, which is of great 
importance for the emergence of this species (Table 
2). Apart from the hypocotyl change, there was no 
adequate development of secondary roots and true 
leaves. The use of cytokinin provided seedlings with 
smaller hypocotyls, but with a larger collar 
diameter, and therefore did not provide adequate 
“hook” formation to pull the cotyledons above the 
substrate (Table 2). The concentration of cytokinin 
used in the pre-germination treatment changed the 
hypocotyl region morphologically, impairing 
germination and emergence of the paricá seeds, 
yielding abnormal plants. 

 



1095 
Pre-germination …  BARDIVIESSO, E. M. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1090-1098, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-41791 

Table 3. Effect of the pre-germination treatment on electrical conductivity (μS cm-1 g-1) and collar diameter 
(mm) in S. amazonicum. 

Treatments  Electrical Conductivity μS cm-
1 g-1 

Collar Diameter 
(mm)  

Scarification   
50% M 7.73 b M 3.73 a 
10%    8.93 a    3.70 a 
Pre-germination treatment   
Non-soaked – Control 21.74 a 3.26 c 
Water 4.41 c 2.99 c 
Gibberellin 4.68 c 2.97 c 
Cytokinin 5.32 c 5.63 a 
Giberelin + Cytokinin 5.20 c 5.26 b 
Potassium Nitrate 8.45 b 2.93 c 
Calcium Nitrate 8.52 b 2.96 c 

CV (%) 14.65 6.34 
MMeans followed by different lowercase letters within a column differ statistically from each other by the Tukey test and by the F-test at 
a 0.05 significance level, respectively. CV = coefficient of variation. 

 
This study verified that the use of 50% 

scarification allowed the seeds to hydrate the tissues 
faster, thus increasing the speed of germination and 
emergence, in addition to plant initial growth. Seed 
hydration with water leads to a higher germination 
speed. In order to increase the plant initial growth 
(length of the hypocotyl and height), the use of 
gibberellin for physiological conditioning is 
recommended. 

Finally, 6-benzylamino-purine cytokinin at 
the concentration of 0.02% used in the pre-
germination treatment is not recommended because 
it caused a reduction in seed performance, in 

addition to inadequate growth. It is worth noting 
that there is a need for studies using other 
concentrations of cytokinin in order to increase 
knowledge of this agent for pre-soaking treatments. 
 
CONCLUSION 

 
Seed pre-soaking with gibberellin after 

mechanical scarification at 50% intensity as a pre-
germination treatment is recommended to obtain 
seeds with higher vigor expression and greater 
initial seedling growth. 

 
 
RESUMO: Sementes de paricá apresentam dormência e após superada pela escarificação mecânica, as 

sementes apresentam germinação lenta e desuniforme. Tratamentos pré-germinativos podem ser utilizados para 
incrementar a performance de germinação de sementes. Assim, o objetivo foi avaliar o potencial fisiológico de 
sementes, crescimento inicial de Paricá após tratamentos pré-germinativos, utilizando diferentes substâncias 
como reguladores vegetais e nutrientes, além da intensidade da escarificação mecânica. O delineamento 
experimental empregado foi o inteiramente casualizado, em esquema fatorial 2x7, constituído pelos tratamentos 
pré-germinativos: escarificação mecânica (10% e 50% do tegumento) e pré-embebição das sementes [controle- 
água, KNO3 0,2%, Ca(NO3)2 0,2%, giberelina 0,02%, citocinina 0,02%, e a mistura da solução de giberelina + 
citocinina (1:1)] além de um grupo controle sem pré-embebição, com quatro repetições. Avaliou-se a 
porcentagem de germinação e emergência, índice de velocidade de germinação e emergência, diâmetro, altura e 
fitomassa seca de plantas, comprimento de plântulas e hipocótilo e condutividade elétrica. A pré-embebição das 
sementes com giberelina após escarificação mecânica de 50% como tratamento pré-germinativo é recomendado 
para obtenção de sementes com maior expressão de vigor e crescimento inicial de plântulas. 
 

PALAVRAS-CHAVE: Giberelina. Citocinina. Pré-embebição. Escarificação mecânica. 
 
 
 
 
 



1096 
Pre-germination …  BARDIVIESSO, E. M. et al. 

Biosci. J., Uberlândia, v. 36, n. 4, p. 1090-1098, July/Aug. 2020 
http://dx.doi.org/10.14393/BJ-v36n4a2020-41791 

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