Viability and Vigour of Sesame (Sesamum indicum L) Seeds
Puspa Hartati, Rosmayati and Diana Sofia Hanafiah
Faculty of Agriculture, Universitas Sumatera Utara. Padang Bulan Medan, Indonesia 20155
Keywords: maximum growth potency, sesame seeds, viability, vigour index.
Abstract: The aim of seed testing was to avoid planting seeds that do not have the ability to grow into expected plants.
Seed germination testing is a method that provide to provide information for seed users about the seeds
ability to grow into plants that have. The viability testing that usually used on sesame seeds is germination
testing. The aim of germination testing is to detect seeds germination viability under optimum condition.
This research has purpose to determine the correlation between germination, vigour index, and maximum
growth potential of sesame seeds. Seeds that used in this research were Sumberejo 4 varieties which have
been stored for 6 and 7 years. Seed germination testing was held based on ISTA Rules method. Germination
testing were carried out on filter paper at temperature changes between 20
o
C and 30
o
C. Seedling evaluation
was carried out on the 3
and 6 days. The vigour index evaluation was carried out on the 3 days. The criteria
of sesame seedlings refers to ISTA Handbook on Seedling Evaluation with germination type E, A-2-1-1-1
seedling group. Abnormal seedlings that were found on the research categorized as rotten seedlings due to
primary infection, damaged primary root, inhibited primary root development, no primary root or missing,
and no hypocotyl. The results showed that seed germination was positively correlated with the vigour index
(r = 0,912**) and maximum growth potential (r = 0,859**), and vigour index was positively correlated with
maximum grwoth potential (r = 0,805**).
1 INTRODUCTION
Seed is one of the basic inputs in agricultural
activities. It is part of plant that used for
reproduction either vegetatively or generatively. The
use of quality seed is one of the efforts in order to
improve productivity. Therefore, the availability of
quality seeds is one of the key to success farming
(Kusandari and Muharram, 2005). Sesame is a plant
that contains 50-53% vegetable oil. Sesame plants
propagation through seeds that produce generatively.
One effort to determine sesame seeds viability is
seed testing.
The main purpose of seed testing is to avoid
planting seeds that do not have the ability to grow
into normal plants. Seed testing reffered to a
germination test. Germination test is one of method
to provide information to seed users about the seeds
ability to grow into productive plants in optimum
environmental conditions (BBPPMBTPH, 2012).
The germination test of seedling in optimum
conditions sometimes show higher percentage of
germination than sprouts in the field. Due to that
conditions, according to Ilyas (2012), germination
test can not provide information about the potential
performance of the seed in the field accurately.
Based on the circumstances, it require an additional
test to obtain information about seed growth in the
field and provide a more sensitive seed quality
assessment.
The test that gives more sensitive seed quality
assessment is vigor test. Vigour test can provide
information about seed quality index; consistent
levels of the potential physical and physiological
quality of seed lots; seed growth on the field; and
seed saving power from a lot. Vigor can be
interpreted as a number of traits that indicate the
activity and seed lots diversity that can grow in
wider range of field conditions (ISTA, 2014).
Seeds that have high vigor will be able to grow
in non optimum environmental conditions and will
produce products above normal in the optimum
environment. In addition, seeds that have high vigor
will grow faster because relatively germination
seeds require a short time (Sadjad et al, 1999).
One of the parameters of the vigour test is the
vigour index. The vigour index can provide more
information about seed vigor. The vigour index
where the seeds have the first calculated value test
Hartati, P., Rosmayati, R. and Hanafiah, D.
Viability and Vigour of Sesame (Sesamum indicum L) Seeds.
DOI: 10.5220/0008547401310134
In Proceedings of the International Conference on Natural Resources and Technology (ICONART 2019), pages 131-134
ISBN: 978-989-758-404-6
Copyright
c
2019 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
131
has a high vigour. One parameter of seed feasibility
is maximum growth potential (Sutopo, 2004). The
value of maximum growth potential shows a high
condition of seed viability (Justice and Bass, 2002).
The seeds used in this study were Sumberejo 4
sesame seeds varieties with two lots which had been
stored for 6 and 7 years. The study aims to
determine the correlation between germination test,
vigour index and maximum growth potential of
sesame seeds.
2 MATERIALS AND METHODS
2.1 Time and Location
The experiment was conducted in laboratory physics
and biology, Seed Testing Laboratory Development
Seed Agency of Quality Testing for Food Crops and
Horticulture, Cimanggis Depok on November-
Desember 2018.
2.2 Materials
Materials that used in this resarch were 2 lots of
SBR 4 sesame seeds varieties. A1 seeds lot was
seeds that have been stored for 7 years and A2 seeds
lot was seeds that have been stored for 6 years. The
seeds were stored in the seeds shed at temperature
between 16-25
o
C. This research was conducted with
three approaches: germination test, vigour index,
and maximum growth potential.
2.3 Methods
Germination test was conducted using ISTA Rules
method in germinator with the temperature changes
between 20
o
C and 30
o
C using filter paper. Sesame
seeds were arranged on filter paper that had been
moistened, then it were germinated in electric
germinator. Germination test of sesame seeds was
evaluated on the 3
and 6 days. Vigour index was
evaluated on 3
days. The criteria for normal
seedlings refer to ISTA Handbook on Seedlings
Evaluation (2006) with germination type E, A-2-1-
1-1seedlings group.
2.3.1 Observation Parameters
1. Germination (G)
The calculation of germination ability was based on
the percentage of normal seedlings on the 3
and 6
days (ISTA, 2014).
G =
Ʃnormal Seedling evaluation (I+II)
× 100%
Ʃ seed planted
2. Vigour index (VI)
Vigour index calculation was based on persentase
the percentage of normal seedlings that grow on the
3
days.
3. Maximum Growth Potential (MGP)
Maximum growth population was calculated based
on the percentage of all seedlings that grow both
normal and abnormal until the end of the
observation. Maximum growth potential was
calculated using:
MGP=
Ʃ seed grow until the end
× 100%
Ʃ seed planted
2.3.2 Data Analysis
This research was conducted using Random Block
Design (RBD), namely seed lot (A1 and A2).
Statistical data processing was performed by
analyzing the F test range at a 95% confidence
interval to see the effect of treatment on the
observed variables. If the treatment has a significant
effect on the benchmark variable of observation,
Duncan Test multiple range test (DMRT) is carried
out at the level of 5%. A simple correlation test was
carried out to see the relationship between the two
variables.
3 RESULTS AND DISCUSSION
3.1 Time and Location
Germination is a series of complex physiological
processes that begin with the process of taking water
(imbibition) by the seed and ending with the
appearance of primary roots penetrating the seed
skin (ISTA, 2014). In the sesame seeds that had been
tested, germination in the laboratory begins with the
appearance of the primary roots penetrating the seed
skin and ends when the seedling have developed to
the phase where the seedlings can be evaluated
according to the ISTA Rules, namely germination
type E, A-2-1-1-1seedlings group.
Sesame seedlings that have reached a certain
development phase, will be evaluated based on
important structures and categorized as normal
seedlings, abnormal seedlings and dead seeds.
Seedlings that were not sufficiently developed,
ICONART 2019 - International Conference on Natural Resources and Technology
132
weak, unbalanced, deformed and damaged, remain
abandoned until the last calculation. ISTA Rules
allow the testing period to be extended if there are
doubts or a large number of seedlings are not normal
(ISTA, 2014). The test can be extended for half the
testing period for germination. Sesame seedlingstest
can be extended for up to three days and evaluation
is carried out on the 9 days.
The results of the study in Table 1, show that the
A2 lot has a germination of 88% while the A1 seed
lot has a germination of 70%. A2 seeds lot is
significantly different from germination, vigour
index and maximum growth potential with A1 seed
lot. The higher the germination value, the greater the
vigour index and the maximum potential for sesame
seed growth in this study.
The vigour index calculation was performed on
the 3 days. The vigour index is one of the parameters
of seed vigour. In general, vigour is defined as the
ability of seeds to grow normally in sub optimal
environmental conditions. Seeds with high vigour
will grow faster because the seeds germinate in a
relatively short time (Sadjad et al, 1999). Data on
Table 1 shows that A2 seed vigour index is
significantly different from A1 lot seed. Although
A2 seed lot was significantly higher than A1 seed
lot, both seeds had a low vigour index.
Maximum growth potential is the sum of
growing seedlings, both normal and abnormal. The
magnitude of the maximum growth potential
indicates a high condition of seed viability (Justice
and Bass, 2002). A1 seed lot had a maximum growth
potential of 90%, where as much as 20% of
seedlings enter the abnormal seedlings category
while A2 seed lot had a maximum growth potential
of 97%, of which 9% in the category of abnormal
seedlings. Abnormal seedlings that were found is in
the category of rotten seedlings due to primary
infection, primary roots damaged due to inhibition
and none, and no hypocotyl (Figure 1).
Table 1:Effect lot of seed on germination, vigour indexand
the maximum growth potential on two lots of sesame
seeds
Seed
Lot
Parameters
Germination
(%)
Vigour index
(%)
Maximum Growth
Potential (%)
A1
70b
13b
90b
A2
88a
20a
97a
Note: The numbers followed by the same letter on the
same line indicates a value not significantly different from
DMRT at α = 5%.
The data in Table 2 shows the correlation
coefficient of each test had strong correlations. The
results of the correlation test between germination
and the value of the vigour index and maximum
growth potential gave the results of a real positive
difference which shows that the higher the value of
the vigour index and the maximum growth potential,
the higher the germination value. The correlation
between the vigour index and the maximum growth
potential gave the results of a real positive difference
indicating that the higher the maximum potential
growth value, the higher the vigour index.
Figure 1: Sesame Seed Evaluation. Normal seedling (A);
Seedling grown rudimentary (B); Abnormal seedling with
no primary root criteria (C), no hypocotyl (D) dan decayed
(E);
Table 2: The correlation coefficient (r) of the germination,
vigour index and the maximum growth potential on two
lots of sesame seeds
Parameter
Germination
(%)
Vigour
index
(%)
Maximum
Growth Potential
(%)
Germination (%)
1
Vigour index (%)
0,912
**
1
Maximum Growth
Potential (%)
0,859
**
0,805
**
1
Note: **: different significantly at the 0.01 level
3.2 Discussion
Sesame in A1 seeds lot (stored 7 years) and A2 lot
(stored 6 years) had a germination rate of 70% and
88%. Both sesame seed lots are able to maintain the
germination of seeds. As for several factors that
A
B
C
E
D
Viability and Vigour of Sesame (Sesamum indicum L) Seeds
133
affect seed germination during storage, namely seed
vigor before storage, seed water content, storage
environment conditions, and storage time (Kartono,
2004).
The data in Table 1 shows that
germination,vigour index and maximum growth
potential of A2 sesame seeds lot are significantly
higher in value than A1 lots. In A1 seeds lot, the
viability value is lower than A2. It can be seen from
the value of germination and the value of the vigour
index. Decreasing the germination of seeds and
increasing the number of abnormal seedlings are one
characteristic of physiologically decreasing seed
vigor (Copeland and Donald, 2001). This is in line
with the maximum growth potential in both seed
lots. Maximum growth potential on A1 seeds lot
were 90% where 20% were abnormal seedlings, on
A2 lot was 97% with 9% were abnormal seedlings.
This indicates that the two lots have experienced a
decrease in vigour.
The high number of abnormal seedlings in A1
and A2 lots is due to the inability of seedlings to
develop into normal seedlings due to seed decline.
Decline in seed quality during storage can occur
when food reserves for embryo growth are reduced
or depleted due to metabolic processes of respiration
(Roberts, 1972). During storage, seeds undergo a
biological process, one of which is the metabolic
process, especially the process of respiration
associated with the process of deteriorating seed
quality.
Seed storage for a long time has a negative
impact on seed viability (Justice et al., 2002). In
addition, seeds that experience a decline in seed
quality will experience a loss of ability to germinate
even though the seeds are in optimum conditions for
germination (Copeland and McDonald, 1995).
The results of this research showed that
germination was positively correlated with the
vigour index (r = 0.912 **) and maximum growth
potential (r = 0.859 *), and the vigour index was
positively correlated with maximum growth
potential (r = 0.805 **). The higher the value of the
vigour index and the maximum growth potential, the
higher the germination. Likewise with the vigour
index, the higher the maximum growth potential of
sesame seeds, the higher the vigour index.
4 CONCLUSIONS
Sesame seed that has been stored for 6 and 7 year
olds were able to maintain germination respectively
88% and 70%. The germination of both sesame seed
lots correlates with the vigour index and maximum
growth potential.
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