Microsoft Word - 3-Agra_41747


367 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 35, n. 2, p. 367-376, Mar./Apr. 2019 
https://doi.org/10.14393/BJ-v35n2a20198-41747 

ADEQUACY OF METHODOLOGY FOR CONDUCTING GERMINATION 
TEST IN FORAGE PEA SEEDS 

 
ADEQUAÇÃO DA METODOLOGIA PARA CONDUÇÃO DO TESTE DE 

GERMINAÇÃO EM SEMENTES DE ERVILHA FORRAGEIRA 
 

Carla Gomes MACHADO
1
; Cibele Chalita MARTINS

2
; Givanildo Zildo SILVA

3
;  

Simério Carlos Silva CRUZ
4
; Raissa Macedo ASSIS

5
 

1. Engenheira Agrônoma, Professora, Doutora, Universidade Federal de Goiás - UFG, Campus Jatobá, Jataí, GO, Brasil; 2. Engenheira 
Agrônoma, Professora Livre-Docente, Faculdade de Ciências Agrárias e Veterinárias - UNESP, Jaboticabal, SP, Brasil; 3. Engenheiro 
Agrônomo, Professor, Pós-Doutorado, Universidade Federal de Goiás - UFG, Campus Jatobá, Jataí, GO, Brasil. Autor correspondente: 

givanildozildo@hotmail.com; 4. Engenheiro Agrônomo, Professor, Doutor, Universidade Federal de Goiás - UFG, Campus Jatobá, 
Jataí, GO, Brasil; 5. Engenheira Agrônoma, Mestranda, Universidade Federal de Goiás - UFG, Campus Jatobá, Jataí, GO, Brasil. 

 
ABSTRACT: Seeds presents variable germination performance at different temperatures and 

substrates, which are basic components of germination test. Within this context, this work aimed to adapt the 
methodology for the seeds germination’s test of P. sativum subsp. arvense. The experiment required four 
portions of seeds, five temperature degrees (15, 20, 25, 20-30 and 15-25 °C), and two substrata (roll of paper 
and in sand). Seeds evaluation considered the following: moisture degree and germination test. The effect of 
seed portion, substrata and temperature in germination was assessed on a daily basis. It was calculated the rate 
of germination, of anormal plants, of dormant and dead seeds, and of speed of germination index; initial, final 
and average times, and synchrony. The experimental design consisted of random blocks with four replications, 
while conjoint analysis was the statistical procedure adopted. The germination test for forage pea seeds should 
be conducted at the constant temperature 20 °C in roll of paper substrate with the first count and final count on 
the 4th and 7th day, respectively. 

 
KEYWORDS: Pisum sativum subsp. arvense. Substratum. Temperature. Quality control. Speed of 

germination. 
 
INTRODUCTION 
 

The production of forage pea (Pisum 
sativum subsp. Arvense) is intended for animal 
feeding (GIORDANO; PEREIRA, 1989; TAN et 
al., 2013; CARGNELUTTI FILHO et al., 2015). In 
addition, this genotype presents important 
characteristics for green manuring and soil 
coverage, being cultivated in the winter, when many 
agricultural areas remain unused in Brazil 
(PINNOW et al., 2013; CARGNELUTTI FILHO et 
al., 2015). 

For commercial P. sativum subsp. arvense 
seeds, regulated by seed standards, the requirements 
are lower as regards the quality of lots in relation to 
large vegetable crops, which is due to the fact that 
the technology involved in the production of seeds 
of this species is less developed in relation to the 
other species cultivated for longer time 
(MACHADO et al., 2011). In the laboratory, 
methods of analysis have been studied, aiming at the 
regular, rapid and complete germination of seeds 
under controlled conditions. Such conditions, 
considered to be optimal, are standardized so that 
the results of germination tests can be reproduced 

and compared, within limits tolerated by the Rules 
for Seed Testing - RAS (BRASIL, 2009). 

For P. sativum subsp. arvense, there is no 
specific methodology for the conduction of the 
germination test in RAS, requiring the adequacy of 
the methodology aiming at the routine use in the 
laboratory of seed analysis. The rules recommend 
for pea, paper and sand substrates, temperature of 20 
°C and evaluations at five and eight days; still 
recommend the use of sand replacing paper, when 
the evaluation of a seed sample is impractical due to 
contamination of the paper substrate (BRASIL, 
2009). The choice of substrate is at the discretion of 
the analytical laboratory, depending on the 
availability of materials and the analyst's familiarity 
with the analytical method. 

Within the quality control program of seed 
companies, germination evaluation is fundamental 
and necessary for successful lot production and 
approval for national and international market 
(BRASIL, 2009; TOMAZ et al., 2015; TOMAZ et 
al., 2016). RAS standards and procedures are 
periodically reviewed by a committee composed of 
researchers and professionals of the area, but 
standards and modifications for new species can 

Received: 16/04/18 
Accepted: 10/10/18 



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Adequacy of methodology…  MACHADO, C. G. et al. 

Biosci. J., Uberlândia, v. 35, n. 2, p. 367-376, Mar./Apr. 2019 

only be added based on research results (TOMAZ et 
al., 2016). In this context, the aim of this study was 
to adapt the methodology for the germination test of 
forage pea seeds. 
 
MATERIAL AND METHODS 
 

For the determination of the methodology 
for conducting the germination test, four 
commercial lots of forage seed were used, with lots 
1 and 2 of BRS cultivar, and lots 3 and 4 of IAPAR 
83 cultivar. These samples were homogenized 
according to RAS (BRASIL, 2009), and after this 
procedure, seeds were conditioned in Kraft paper 
bags, kept in controlled environment at 5 °C until 
the experiment was carried out, in which they were 
submitted to determinations described below. 

Water content - evaluated by the stove 
method at 105 ± 3 °C for 24 h (BRASIL, 2009) 
using two subsamples of 5.0 g of seeds per lot. 

Germination test - conducted with four 
subsamples of 100 seeds on two substrates: roll of 
paper towel - sheets were moistened with deionized 
water in the amount of 2.5 times the mass of the 
non-hydrated paper; and sand at two centimeters 
deep and moistened to 60% holding capacity, kept 
inside transparent plastic trays (30.2 x 20.8 x 6.3 
cm). Prior to use, sand was sieved and sterilized at 
200 °C for two hours. After sowing, the boxes and 
the rolls were packed in plastic bags to avoid 
dehydration of substrates (COIMBRA et al., 2007). 
Normal seedlings were those whose epicotyl had 
surpassed the sand and when they reached one 
centimeter of length in the paper roll, and counts 
were performed until germination stabilization. 

During the germination test, seeds were kept 
in a germination chamber under constant (15, 20 
and 25 °C) and alternated temperature conditions 
(20-30 °C and 15-25 °C), under a photoperiod of 8 h 
light. 

In addition to the percentage of 
germination at the end of the test, the percentage 
of abnormal seedlings, dormant and dead seeds 
was counted. For this, the sand substrate was 
passed in a sieve for visual evaluation of the 
remaining seeds with the aid of tweezers. 

Speed of germination index - performed by 
means of daily counts during the germination test, 
according to formula described by Maguire (1962). 
The initial, final and mean times and the 
germination synchrony according to formulas of 
Santana and Ranal were also obtained (2004). 

In the statistical procedure, temperatures of 
15, 20, 25, 20-30 and 15-25 °C were studied in 
independent experiments, using a randomized 
complete block design with four replicates. In all 
experiments, four lots and two substrates distributed 
in the factorial scheme (4 x 2) were evaluated. After 
obtaining data, analyses of variance of each 
experiment were performed. 

After individual analyses, combined 
analyses were programmed to evaluate the effect of 
temperature on germination. The combined analysis 
of experiments was carried out, as it was not 
possible to randomize the temperatures in different 
germination chambers, in addition, due to the 
importance of temperature on the germination 
process, both regarding total germination and the 
speed of germination, in order to identify the best 
temperature for the germination of forage pea seeds. 
For comparison of means, the Tukey test was used 
at 5 and 1% probability. 

 
RESULTS AND DISCUSSION 
 

The summary of the analysis of variance of 
the normal and abnormal seedlings data, dead and 
dormant seeds, initial, final and average time, 
germination speed index (SGI) and synchrony 
obtained in the conjoint analysis of the experiments 
conducted with different temperatures are presented 
in Table 1. It was noted by the results that there was 
significant interaction by the F test, between 
substrates and temperatures for dead seeds and final 
and average times; between lots and temperatures 
for abnormal seedlings, dead seeds and average 
time. Substrates, lots and temperatures for normal 
seedlings, initial time, SGI and synchrony, also 
presented interaction. 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 



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Table 1. Summary of the analysis of variance of the data percentage of normal and abnormal seedlings, 
dormant and dead seeds was counted, initial, final and mean times, Speed of germination index (SGI) 
and the germination synchrony (S), obtained in the conjoint analysis of the experiments conducted 
with different temperatures. 

SV DF 

Mean square 

Seedlings Seeds Time 

SGI GS 
Normal Abnormal Dead Dormant Initial Final  Mean 

Substrate (S) 1 135,1** 5,3ns 1709,6** 752,6** 0,1ns 42,0** 1,6** 55,3** 0,0ns 

Lot (L) 3 33540,0**603,8** 12399,9**2785,3** 10,3** 12,2** 16,8** 2015,7** 0,2** 

S x L 3 23,1ns 41,1ns 378,2** 361,7** 0,6** 0,3ns 0,3* 13,5** 0,1** 

Temperature (T) 4 360,6** 59,4* 711,2** 13,6ns 24,2** 50,1** 39,8** 198,1** 0,1** 

S x T 4 166,7** 10,4ns 184,5** 25,4ns 3,2** 4,2* 1,8** 5,0** 0,1** 

L x T 12 56,7** 64,3** 205,0** 21,3ns 0,7** 2,3ns 1,3** 19,1** 0,1** 

S x L x T 12 68,2** 9,2ns 55,6ns 19,3ns 0,2* 0,6ns 0,2ns 6,0** 0,1* 

Block (T) 15 23,4ns 7,9ns 70,0* 42,2* 0,1ns 1,5ns 0,3** 0,7ns 0,0ns 

Residue 105 16,1 17,1 36,8 19,6 0,1 1,3 0,1 0,9 0,0 

CV (%) 6,1 43,1 37,5 53,4 7,6 15,4 6,2 6,9 24,5 
**, *and ns: significant at 1%, 5% and non-significant according the F test, respectively. SV: Source of variation. DF: Degrees of 
freedom. 
 

The seeds of the four lots of forage pea 
presented water contents between 9.6 and 9.9%, 
during the installation of experiments. Thus, lots 
had maximum variation of 0.4% in the water 
content; this value is acceptable according to the 
tolerance table established by the Rules for Seed 
Testing (BRASIL, 2009). Silva et al. (2017) 

working with forage legume, crotalária (Crotalaria 
juncea L.), reported that the small variation between 
water contents provides more accurate 
determination of the methodology and the 
differences between lots can be attributed to the 
physiological characteristics of seeds. 

 
Table 2. Interaction between substrate and lots for variables obtained in the germination test of Pisum sativum 

subsp. arvense seeds conducted at temperatures of 15, 20, 25, 20-30 and 15-35 °C. 

Variables Substrates 
Lots 
1 2 3 4 

15 °C 

Germination (%) 
Paper 98 aA1 85 aB 64 aC 33 aD 
Sand 95 aA 88 aB 57 bC 38 aD 

Dead seed (%) 
Paper 0 aA 1 aA 8 aA 18 aB 
Sand 0 aA 2 aA 19 bB 30 bC 

Speed of germination index 
Paper 16,75 aA 14,30 aB 8,32 aC 3,71 aD 
Sand 15,34 bA 14,70 aA 8,37 aB 4,57 aC 

Synchrony 
Paper 0,39 bAB 0,40 aA 0,24 bC 0,29 aBC 
Sand 0,52 aA 0,39 aB 0,34 aB 0,22 aC 

20 °C 

Germination (%) 
Paper 96 aA 86 aB 63 aC 30 bD 
Sand 94 aA 84 aB 60 aC 38 aD 

Initial time (days) 
Paper 3,0 bB 3,0 bB 4,0 aA 4,5 aA 
Sand 4,0 aB 4,0 aB 4,0 aB 4,8 aA 

Speed of germination index Paper 25,34 aA 22,60 aB 14,03 aC 5,67 aD 



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Biosci. J., Uberlândia, v. 35, n. 2, p. 367-376, Mar./Apr. 2019 

Sand 21,96 bA 19,60 bB 12,56 bC 6,75 aD 

Synchrony 
Paper 0,45 aA 0,40 bA 0,45 aA 0,41 aA 
Sand 0,58 aA 0,59 aA 0,40 aAB 0,24 bB 

25 °C 

Germination (%) 
Paper 94 aA 89 aB 51 aB 24 aC 
Sand 94 aA 82 aB 56 aC 23 aD 

Dead seeds (%) 
Paper 2 aA 2 aB 24 aB 40 aC 
Sand 1 aA 6 bA 34 bB 56 bC 

Dormant seeds (%) 
Paper 0 aA 2 aA 19 bB 24 bB 
Sand 0 aA 5 aAB 3 aA 10 aB 

Speed of germination index 
Paper 25,08 aA 24,90 aA 12,08 aB 5,23 aC 
Sand 25,16 aA 20,90 bB 13,20 aC 4,90 aD 

20-30 °C 

Germination (%) 
Paper 94 aA 81 aB 45 bC 23 aD 
Sand 93 aA 75 aB 54 aC 28 aD 

Speed of germination index 
Paper 21,50 aA 18,97 aB 9,71 aC 4,65 aD 
Sand 17,40 bA 14,28 bB 10,33 aC 4,84 aD 

Synchrony 
Paper 0,45 aA 0,43 aA 0,55 aA 0,64 aA 
Sand 0,54 aA 0,52 aA 0,48 aA 0,35 bA 

15-25 °C 

Dead seeds (%) 
Paper 0 aA 1 aA 11 aA 26 aB 
Sand 3 aA 5 aA 33 bB 53 bC 

Dormant seeds (%) 
Paper 1 aA 2 aA 20 aB 22 bB 
Sand 2 aA 2 aA 7 aAB 14 aB 

1 Means followed by the same letter, lowercase in the column and uppercase in the row, for each temperature, do not differ by the Tukey 
test at 5% probability. 
 

Table 2 shows the interaction between 
substrate and lots. For temperature of 15 °C, these 
factors had interaction for germination, dead seed, 
speed of germination index and synchrony. The 
germination percentage had a decrease from lot 1 to 
4, with difference between substrates only in lot 3, 
for which paper showed better result. This 
germination behavior is similar in other 
temperatures, except that difference between 
substrates was verified only at 20-30 °C, with seeds 
sown in sand with higher germination and no 
interaction between factors for this variable at 
temperature of 15-25 °C was verified. 

Higher percentages of dead seeds were 
observed at temperatures of 15, 25 and 15-25 °C in 
sand substrate in lots 3 and 4. Similar result was 
verified for percentage of dead seeds at 
temperatures of 25 and 15-25 °C in paper substrate 
for lots 3 and 4. 

The paper roll substrate provided seeds of 
lot 1 higher speeds of germination at all 
temperatures when compared to the other lots and to 
the sand substrate, except at 25 °C, in which it did 
not differ between substrates used and in this 

temperature, lots 1 and 2 provided similar speed of 
germination on the paper substrate. It is also 
noteworthy that at temperature of 15-25 °C, there 
was no interaction between factors for this variable. 

The germination synchrony was not 
efficient in the differentiation of lots and substrates 
at temperatures of 15, 20 and 20-30 °C, since there 
were conflicting and different results compared to 
the other tests, classifying lot 4 (worse quality) 
equal to lot 1 (best quality). 

The isolated effect of substrates (Table 3) 
on mean and final time was lower on paper substrate 
at temperatures of 20, 25, 20-30 °C, and shorter 
initial time was observed in seed sown on paper at 
20-30 °C and in sand at 15-25 °C. The paper 
substrate provided higher percentage and speed of 
germination for forage pea seeds sown at 15-25 °C, 
for variables germination, speed of germination 
index and synchrony. 

 
 
 
 
 

 



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Table 3. Means of variables obtained in the germination test of Pisum sativum subsp. arvense seeds conducted 
in two substrates at temperatures of 20, 25, 20-30 and 15-35 °C. 

Variables Substrates 
 

Variables Substrates 

20 °C 
 

25 °C 

Time (days) 

Mean 
Paper 4,5 a1 

 

Time (days) 

Mean 
Paper 4,1 a 

Sand 4,9 b 
 

Sand 4,3 b 

Final 
Paper 5,9 a 

 Final 
Paper 5,8 a 

Sand 7,0 b 
 

Sand 6,9 b 

20-30 °C 
 

15-25 °C 

Dormant seeds (%) 
Paper 10,0 b 

 Germination (%) 
Paper 70 a 

Sand 6,0 a 
 

Sand 61 b 

Time (days) 

Initial 
Paper 3,6 a 

 Initial time (days) 
Paper 5,0 b 

Sand 4,3 b 
 

Sand 4,3 a 

Mean 
Paper 4,6 a 

 Speed of germination 
index 

Paper 12,90 a 

Sand 5,5 b 
 

Sand 11,60 b 

Final 
Paper 6,0 a 

 Synchrony 
Paper 0,57 a 

Sand 8,1 b 
 

Sand 0,43 b 
1 Means followed by the same letter, lowercase in the column, for each temperature, do not differ by the Tukey test at 5% probability. 
 

The best germination performance of forage 
pea seeds in paper substrate can be attributed to the 
vegetative structure's development lower physical 
impairment and higher aeration of this substrate in 
comparison to sand. Probably for this species, these 
factors must be more important than the contact 
surface, which favors water absorption (PACHECO 
et al., 2014; OLIVEIRA et al., 2016). In the 
germination of forage pea, the plumule is folded and 
fixed to the epicotyl, which grows by perforating the 
sand layer, dragging the primary leaves (BRASIL, 
2009; CARVALHO; NAKAGAWA, 2012). Thus, 
the seedling needs more energy to break the sand 

layer during the germination process than in paper 
subtract, a fact that may explain the lower 
percentage of dormant seeds verified for seeds sown 
in sand at temperature of 20-30 °C. 

When variables that were influenced only 
by the lot factor were evaluated, Table 4, it was 
verified that lot 1 and 2 are of high quality, lot 3 of 
intermediate quality and lot 4 of low quality. Since 
there is a decrease in speed and percentage of 
germination from lot 1 to 4, the opposite 
performance was verified for variables abnormal 
seedlings, dead and dormant seeds. 

 
Table 4. Means of variables obtained in the germination test of four Pisum sativum subsp. arvense seed lots 

conducted at temperatures of 15, 20, 25, 20-30 and 15-35 °C. 

Variables 
Lots 

1 2 3 4 

15 °C 

Abnormal seedlings (%) 4 A1 11 B 13 B 18 C 

Dormant seeds (%) 0 A 1 A 13 B 23 C 

Time (days) 

Initial 5,1 A 5,0 A 5,8 B 6,9 C 

Mean 6,1 A 6,1 A 7,4 B 8,8 C 

Final 8,1 A 8,6 A 9,8 AB 11,1 C 

20 °C 

Abnormal seedlings (%) 5 A 10 A 8 A 18 B 

Dead seeds (%) 0 A 3 A 21 B 30 B 



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Dormant seeds (%) 0 A 3 A 10 B 18 C 

Time (days) 
Mean 4,1 A 4,1 A 4,8 B 5,6 C 

Final 5,9 A 6,0 AB 6,6 AB 7,3 B 

25 °C 

Abnormal seedlings (%) 5 A 7 AB 7 AB 12 B 

Time (days) 
Initial 3,0 A 3,0 A 3,8 B 4,1 C 

Mean 3,9 A 3,9 A 4,3 B 4,8 C 

Synchrony 0,46 AB 0,52 AB 0,60 A 0,42 B 

20-30 °C 

Abnormal seedlings (%) 5 A 14 C 10 AB 8 AB 

Dead seeds (%) 1 A 4 A 29 B 49 C 

Dormant seeds (%) 1 A 4 AB 11 BC 17 C 

Time (days) 
Initial 3,5 A 3,5 A 4,4 B 4,4 B 

Mean 5,0 AB 4,9 A 5,0 AB 5,4 B 

15-25 °C 

Germination (%) 93 A 83 B 55 C 31 D 

Abnormal seedlings (%) 4 A 12 B 10 AB 12 B 

Mean time(days) 5,2 A 5,2 A 5,8 B 6,4 C 

Speed of germination index 18,30 A 16,20 B 9,69 C 4,88 D 

Synchrony 0,66 A 0,65 A 0,35 B 0,33 B 
1 Means followed by the same letter, uppercase in the row, for each temperature, do not differ by the Tukey test at 5% probability. 
 

The identification of high quality lots is a 
prime factor during seed production programs as an 
important strategy for seed quality control as they 
help ensuring of the plant population in the field 
(SILVA et al., 2017). 

Aiming at identifying the best temperature 
for the germination of forage pea seeds, the 
combined analyses of experiments was performed, 

because it is not possible to randomize the 
temperatures in different germination chambers. The 
effect of temperature on interaction with the 
substrate and seed quality (Lot) on germination, 
initial time, speed of germination index and 
germination synchrony was verified in combined 
analyses (Table 5). 

 
Table 5. Combined analyses of the interaction between temperature (T), substrates and lots in the evaluation of 

variables of the germination test of Pisum sativum subsp. arvense seeds. 

Variables T °C 
Lots/Substrates 

1 2 3 4 

Paper Sand Paper Sand Paper Sand Paper Sand 

G
er

m
in

at
io

n 
(%

) 

15 98 a1 95 a 85 ab 88 a 64 a 57 a 33 ab 38 a 

20 96 a 94 a 86 ab 84 a 63 a 60 a 30 bc 38 a 

25 94 a 94 a 89 a 83 ab 51 b 56 a 24 c 23 b 

20-30 94 a 93 a 81 b 75 b 45 b 54 ab 23 c 28 b 

15-25 96 a 91 a 85 ab 81 ab 62 a 48 b 39 a 24 b 

In
it

ia
l 

ti
m

e 
(d

ay
s)

 

15 5,0 b 5,3 c 5,0 b 5,0 c 6,0 c 5,5 d 7,3 c 6,5 b 

20 3,0 a 4,0 b 3,0 a 4,0 b 4,0 a 4,0 ab 4,5 a 4,6 a 

25 3,0 a 3,0 a 3,0 a 3,0 a 4,0 a 3,5 a 4,0 a 4,3 a 



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20-30 3,0 a 4,0 b 3,0 a 4,0 b 4,0 a 4,8 c 4,3 a 4,5 a 

15-25 5,0 b 4,0 b 5,0 b 4,3 b 5,0 b 4,3 bc 5,3 b 4,5 a 
S

p
ee

d
 

of
 

g
er

m
in

at
io

n
 

in
d

ex
 

15 16,8 c 15,3 d 14,3 e 14,7 b 8,3 d 8,4 c 3,7 b 4,6 b 

20 25,4 a 21,9 b 22,6 b 19,6 a 14,0 a 12,6 a 5,7 a 6,6 a 

25 25,1 a 25,2 a 24,9 a 20,8 a 12,1 b 13,2 a 5,2 ab 4,9 ab 

20-30 21,5 b 17,4 c 18,9 c 14,3 b 9,7 cd 10,3 b 4,7 ab 4,8 b 

15-25 18,6 c 17,9 c 16,6 d 15,8 b 10,8 bc 8,6 bc 5,8 a 3,9 b 

S
y

n
ch

ro
n

y 

15 0,39 b 0,52 a 0,40 b 0,39 a 0,24 c 0,34 b 0,29 b 0,22 a 

20 0,45 b 0,58 a 0,40 b 0,59 a 0,45 abc 0,40 ab 0,41 ab 0,24 a 

25 0,37 b 0,54 a 0,42 b 0,61 a 0,60 a 0,60 a 0,44 ab 0,39 a 

20-30 0,45 b 0,54 a 0,43 b 0,52 a 0,55 a 0,48 ab 0,64 a 0,35 a 

15-25 0,75 a 0,57 a 0,79 a 0,50 a 0,36 b 0,34 b 0,36 b 0,30 a 
1 Means followed by the same letter, lowercase in the column, for each substrate, do not differ by the Tukey test at 5% probability. 
 

Temperature had a significant effect on 
germination as the quality of lots reduced, with 
better performance of seeds under conditions of 
mild temperatures (15 and 20 °C). This result is 
probably because pea is originated in the Middle 
East, so that the culture develops and produces well 
in regions with temperature between 4 and 30 °C 
and temperature of 18 °C is considered ideal 
(VIEIRA et al., 2007; CARVALHO et al., 2012; 
TORALES et al., 2014). 

In relation to the speed of germination, it 
was observed for the initial time and speed of 
germination index that the temperature of 15 °C for 
all lots in both substrates was the one that presented 
worse performance with the longest time to start 
germination and lower speed of germination index. 
For these variables, the best performance of constant 
temperatures of 20 and 25 °C is highlighted, and for 
the initial time, temperature of 20-30 °C is also 
highlighted. 

The best seed performance at 25 °C for 
variables that evaluate speed of germination can be 
attributed to the fact that at higher temperatures, the 
water absorption and chemical reactions rates are 
higher, and seeds germinate more rapidly 
(CARVALHO; NAKAGAWA, 2012). 

Therefore, the temperatures most favorable 
for the speed of germination were higher than those 
observed to obtain the maximum percentage of 
germination. This phenomenon can be explained by 
the acceleration of metabolic reactions of seeds due 
to the high temperatures, associated with protein 
denaturation and alteration of cell membranes, so 
that the number of seeds that can complete the 
germination reduces rapidly (KAPOOR et al., 
2011). 

The germination synchrony was influenced 
by temperatures mainly for paper substrate, because 
for sand substrate in all lots except for lot 3, 
temperature did not exert significant influence. On 
the paper substrate for lots 1 and 2, the germination 
of seeds was more synchronized at temperature of 
15-25 °C, that is, the germination distribution in 
time was more regular than in the other treatments. 

Table 6 shows the effect of temperature in 
interaction with the substrate, on the incidence of 
dead seeds and final and medium germination times. 
For the percentage of dead seeds, it was observed 
that in the paper substrate, the temperature of 15 °C 
obtained the lowest percentage of dead seeds, not 
differing only from those sown at 15-25 °C. In the 
sand substrate, the temperatures of 15 and 20 °C 
presented smaller percentages of dead seeds in 
comparison to the other evaluated temperatures, 
which did not differ from each other. The 
availability of oxygen may be related to the higher 
percentages of dead seeds (ZUCARELI et al., 
2009), so at higher temperatures, oxygen availability 
is reduced by increasing the percentage of dead 
seeds (GAZOLA et al., 2014). 

 
 
 
 
 
 
 
 
 
 

 



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Table 6. Combined analysis of the interaction between temperature (T) and substrates, as well as temperature 
and lots in the evaluation of variables of the germination test of Pisum sativum subsp. arvense seeds 

Variables T (°C) 
Substrates 

 Variables T (°C) 
Lots 

Paper Sand 
 

1 2 3 4 

D
ea

d
 s

ee
d

s 
(%

) 

15 7 a1 13 a 
 

A
b

n
o

rm
al

 
se

ed
li

n
gs

 (
%

) 

15 4 a 11 ab 13 b 18 b 

20 13 bc 15 a 
 

20 5 a 10 ab 7 ab 18 b 

25 17 cd 24 b 
 

25 5 a 7 a 6 a 12 a 

20-30 19 d 22 b 
 

20-30 5 a 14 b 10 ab 8 a 

15-25 9 ab 23 b 
 

15-25 4 a 12 ab 10 ab 12 b 

M
ea

n
 t

im
e 

(d
ay

s)
 

15 7,2 d 7,0 d 
 

D
ea

d
 s

ee
d

s 
(%

) 

15 0 a 2 a 13 a 24 a 

20 4,5 b 4,9 b 
 

20 0 a 3 a 21 ab 30 a 

25 4,1 a 4,3 a 
 

25 1 a 4 a 29 b 49 c 

20-30 4,6 b 5,5 c 
 

20-30 1 a 4 a 29 b 49 c 

15-25 5,7 c 5,6 c 
 

15-25 1 a 3 a 22 b 39 b 

F
in

al
 t

im
e 

 
(d

ay
s)

 

15 9,2 c 9,6 c 
 

M
ea

n
 t

im
e 

(d
ay

s)
 

15 6,1 c 6,1 c 7,4 d 8,8 d 

20 5,9 a 7,0 a 
 

20 4,1 a 4,2 a 4,8 ab 5,6 b 

25 5,8 a 6,9 a 
 

25 3,9 a 3,9 a 4,3 a 4,8 a 

20-30 6,0 a 8,1 b 
 

20-30 5,0 b 4,9 b 5,0 b 5,4 b 

15-25 7,6 b 8,0 ab 
 

15-25 5,2 b 5,2 b 5,8 c 6,4 c 
1 Means followed by the same letter, lowercase in the column, for each substrate or lot, do not differ by the Tukey test at 5% probability. 
 

Lower mean and final germination times 
were found for seeds maintained at 25 °C, 
regardless of substrate, except for paper substrate 
that this temperature was similar to 20 and 20-30 °C 
and in the sand substrate, temperature was similar to 
20 and 15- 25 °C, at the final germination time. 

Table 6 shows too the effect of temperature 
in interaction with seed quality (Lot), on the 
incidence of abnormal seedlings, dead seeds and the 
average time for germination. For abnormal 
seedlings, lot 1 did not present statistical difference 
among temperatures. In lots 2 and 3, temperature of 
25 °C provided lower percentage of abnormal 
seedlings in relation to temperature of 20-30 and 15 
°C, respectively, and the others were not statistically 
different. For lot 4, temperatures of 25 and 20-30 °C 
did not differ and presented smaller percentage of 
abnormal seedlings in relation to the other 
temperatures. 

The percentage of dead seeds of lots 1 and 2 
were similar among evaluated temperatures. Lot 3 
presented lower percentage of dead seeds at 15 °C 
compared to temperatures of 25, 20-30 and 15-25 
°C, which did not differ from each other and 
temperature of 20 °C presented intermediate mean 
and not statistically different from the others. For lot 
4, temperatures 15 and 20 °C did not differ from 
each other and presented lower percentage of dead 

seeds in comparison to the others. Conversely, 
temperatures of 25 and 20-30 °C also did not show 
statistical difference, being the temperatures that 
presented the highest percentages of dead seeds in 
comparison to the others. 

It is noteworthy that all temperatures 
evaluated presented more than 24% of dead seeds 
for lot 4, highlighting temperatures of 25 and 20-30 
°C with almost 50% of dead seeds, being one of the 
evidences of low quality of this lot. 

For the average germination time of forage 
pea, it was verified by the means of lots 1 and 2, as 
well as for dead seeds, that they presented the same 
behavior among themselves, being that in this case, 
differences among temperatures were observed. At 
temperature of 15 °C, the highest average time was 
obtained and the lowest at temperatures of 20 and 
25 °C, the latter were not different from each other. 
Lots 3 and 4 presented similar behavior, also 
showing the highest average time at temperature of 
15 °C in relation to the others. For lot 3, the average 
germination time at 20 °C did not differ statistically 
from temperatures of 25 and 20-30 °C with the 
lowest average time. As for lot 4, the lowest mean 
time was observed at temperature of 25 °C. 

In general, temperature of 20 °C stood out 
in relation to the others and paper substrate 
presented better performance in relation to sand 



375 
Adequacy of methodology…  MACHADO, C. G. et al. 

Biosci. J., Uberlândia, v. 35, n. 2, p. 367-376, Mar./Apr. 2019 

substrate mainly in relation to the speed of 
germination, in addition to being a substrate easy to 
handle because it facilitates the counting and 
extraction of seedlings, disposal and storage. 

We can also emphasize that the first count 
of forage pea germination can be done on the 4th day 
after sowing, since the final germination percentage 
of the most vigorous lot on this day presents 50% + 
1 of the total germinated seedlings and can be used 
as an indication of vigor, in addition to reducing the 
sources of contamination and facilitating the final 

germination reading. The final germination reading 
can be done on the 7th day after sowing, as from this 
day, germination of seedlings is stabilized. 

 
CONCLUSIONS 
 

The germination test for forage pea seeds 
should be conducted at the constant temperature 20 
°C in roll of paper substrate with the first count and 
final count on the 4th and 7th day, respectively 

 
 

RESUMO: As sementes apresentam desempenho germinativo variável em diferentes temperaturas e 
substratos, que são componentes básicos do teste de germinação. Dentro deste contexto, este trabalho teve 
como objetivo adequar a metodologia para o teste de germinação de sementes de P. sativum subsp. arvense. 
Para tanto, foram utilizados quatro lotes de sementes, cinco temperaturas (15, 20, 25, 20-30 e 15-25 °C) e dois 
substratos (rolo de papel e entre areia). O teor de água das sementes foi determinado antes das avaliações e o 
efeito dos lotes, substratos e temperaturas sobre a germinação foi avaliado diariamente.  Calculou-se a 
porcentagem de germinação, de plântulas anormais, de sementes dormentes e mortas, o índice de velocidade de 
germinação, os tempos inicial, final e médio e sincronia. O delineamento adotado foi o de blocos casualizados, 
com quatro repetições e o procedimento estatístico adotado foi análise conjunta. O teste de germinação deve ser 
conduzido na temperatura constante de 20 °C, em substrato rolo de papel com primeira contagem e contagem 
final ao 4° e 7° dia, respectivamente. 

 
PALAVRAS-CHAVE: Pisum sativum subsp. arvense. Substrato. Temperatura. Controle de qualidade. 

Velocidade de germinação. 
 
 
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