Microsoft Word - 3-Agra_29241.doc
1452
Original Article
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
PHYSIOLOGICAL POTENTIAL OF IRRIGATED RICE SEEDS TREATED
WITH AMINO ACIDS AND UNDER SALT STRESS
POTENCIAL FISIOLÓGICO DE SEMENTES DE ARROZ IRRIGADO TRATADAS
COM AMINOÁCIDOS E SUBMETIDAS A ESTRESSE SALINO
Elisa Souza LEMES
1
; Leticia DIAS
2
; Thaís D'Avila ROSA
3
; Vânia Marques GEHLING
4
;
Sandro de OLIVEIRA
5
; André Oliveira de MENDONÇA
6
; Géri Eduardo MENEGHELLO
7
1. Engenheira Agrônoma, Doutoranda em Ciência e Tecnologia de Sementes, Universidade Federal de Pelotas – UFPel, Pelotas, RS,
Brasil. lemes.elisa@yahoo.com.br; 2. Engenheira Agrônoma, Doutoranda em C&T de Sementes, UFPel, Pelotas, RS, Brasil; 3.
Engenheira Agrônoma, Doutoranda em C&T de Sementes, UFPel, Pelotas, RS, Brasil; 4. Bióloga, Doutoranda em C&T de Sementes,
UFPel, Pelotas, RS, Brasil; 5. Engenheiro Agrônomo, Doutorando em C&T de Sementes, UFPel, Pelotas, RS, Brasil; 6. Biólogo,
Doutorando em C&T de Sementes, UFPel, Pelotas, RS, Brasil; 7. Engenheiro Agrônomo, Doutor em C&T de Sementes, UFPel, Pelotas,
RS, Brasil.
ABSTRACT: Salt stress in rice plants affects growth, development and crop yield. However, seed treatment
can reduce the deleterious effects caused by salt stress. The use of amino acids in agriculture has increased, both in Brazil
and in other countries, due to higher productivity and provide better quality of plants treated with amino acids. The
objective of this study was to evaluate the effect of amino acid coating on the physiological potential of rice seeds under
salt stress. The experimental design was a completely randomized three-way factorial design with two batches of seeds,
two levels of amino acid treatment (with or without amino acid) and five salt concentrations (0.0, 25.0, 50.0, 75.0 and
100.0 mM) with four replicates. The physiological quality of seeds was assessed by a germination test, first germination
count, cold test, accelerated aging, seedling shoot and root lengths, and dry weight of shoots and roots. It is concluded that
the seed treatment with amino acids results in better physiological performance of rice seeds when subjected to salt stress,
which affects negatively the physiological quality of seeds.
KEYWORDS: Oryza sativa L. Salinity. Germination. Vigor. Coating.
INTRODUCTION
Rice (Oryza sativa L.) is the third most-
produced cereal in the world, second only to wheat
and corn (USDA, 2013). Brazil is among the top ten
producers of rice, the largest producer outside Asia
(VAN NGUYEN; FERRERO, 2006). One of the
main rice irrigation systems is to flood the rice
fields, which can lead to soil salinization in fields
with poor drainage, especially in cropping areas that
use sea water. Therefore salinity is one of the most
significant environmental constraints on rice
production (LIMA, 2008).
Salt stress in rice plants can be triggered by
the presence of excess salts in the soil, or by
introduction of the cropping system through
irrigation water. In both cases, a large concentration
of salts affects growth, development, and
productivity of the culture (BENITEZ et al., 2010),
due to the increased osmotic pressure of the soil
solution and the accumulation of excess ions in
plant tissue. Excess ions may be toxic or cause other
nutrient deficiencies, or in alteration of the
nutritional status of the plants, for the absorption
abilities and nutritional requirements
(SCIVITTARO et al., 2009). Thus, seed treatment
may reduce the deleterious effects caused by salt
stress.
According to Bays et al. (2007), the primary
requirement of an increasingly competitive market
is to add value to the seeds, using production
methods and technologies such as seed treatment.
Currently, treatment is used to incorporate materials
such as fungicides, micronutrients, pesticides, plant
hormones and polymers which improve the
performance of seeds and seedlings and even later
stages of culture.
Amino acids are organic molecules formed
by a carbon (α) connected to four chemical groups:
one amine group (NH2), a carboxylic group
(COOH), a hydrogen atom and a side group
(radical); these organizational units can meet and
form larger molecules called proteins, which are
formed from 20 amino acids (ROSSETTI, 2012). In
plants, amino acids serve as precursors of
chlorophyll, polyamides important in early cell
proliferation, lignin which gives rise to the
formation of woody tissues, and indol acetic acid
which is a natural auxin (plant growth regulator).
Amino acids also participate in the synthesis of
other amino acids and chlorophyll, and act as
organic nitrogen reserves, regulate water balance,
have anti-stress and anti-senescence effects, act in
Received: 28/02/16
Accepted: 05/10/16
1453
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
the formation of cell walls, play an important role in
hormone metabolism, and induce the mechanism of
viral resistance (PRIYACHEM, 2014a).
The application of amino acids in crops is
not intended to meet the protein synthesis needs of
plants but to activate physiological metabolism
(FLOSS; FLOSS, 2007). The use of amino acids in
agriculture has increased, both in Brazil and in other
countries, due to the higher yields and better quality
of a variety of cultured plants (BRANDÃO, 2007).
In addition, other benefits of using amino acids that
have been cited by Brandão (2007), are metabolic
balance, improved photosynthesis, decreased
phytotoxicity of some pesticides, increased
tolerance to pests and diseases, better absorption and
translocation of nutrients applied to the leaves
improving the development and strength of the root
system, better hormonal regulation, improved
tolerance to water stress and frost, increased
flowering, and increased quality of the harvested
products.
The aim of this study was to evaluate the
effect of amino acids applied to seeds on the
physiological performance of batches of rice seeds
submitted to salt stress.
MATERIAL AND METHODS
The research was conducted in the Flavio
Farias Rocha Seed Testing Laboratory (LDAS) of
the Department of Plant Science, Eliseu Maciel
Faculty of Agriculture (FAEM) of the Federal
University of Pelotas (UFPel). Seeds of two batches
of rice seeds of the cultivar IRGA 424 were used,
considered moderately tolerant to salinity.
The experimental design was completely
randomized with three factorial arrangements of: 1)
Batches – lot 1 and lot 2; 2) Amino acid treatment –
with or without amino acid; 3) Salt treatment – 0.0,
25.0, 50.0, 75.0 and 100.0 mM; with four
replications.
The seeds were coated with the commercial
product Amino Plus® and the ColorSeed® polymer
at doses of 400 mL 100 kg-1 of seed and 300 mL
100 kg-1 of seed, respectively. The use of the
polymer in the treatment was to improve adhesion
of the amino acid product to the seed. The
proportion of the spray volume was maintained at
1200 mL 100 kg-1 of seed by adding water, and this
proportion was maintained in the control treatment
of water and polymer only. Seed coating was done
using a manual method described by Nunes (2005)
which mixes seeds and products in plastic bags (3
L). The products were applied directly to the bottom
of the plastic bag and spread to a height of about 15
centimeters, after which 0.1 kg of seeds was placed
inside the plastic bag and shaken vigorously for
three minutes. After mixing seeds and products the
bags were opened for the seeds to dry at room
temperature for a period of 24 hours.
The product Amino Plus® has 14 amino
acids: alanine (1.164%); arginine (0.189%); aspartic
acid (1.943%); glutamic acid (3.316%); glycine
(0.202%); isoleucine (0.171%); leucine (0.268%);
lysine (0.240%); phenylalanine (0.143%); serine
(0.179%); threonine (0.188%); tryptophan
(0.175%); tyrosine (0.122%); valine (0.288%); and
nutrients N (11%) and K2O (1%) (AJINOMOTO,
2013).
After treatment, seeds were evaluated with
the following laboratory tests:
Germination (G) test: conducted with 200
seeds, with four replicates of 50 seeds per
experimental unit. Germitest paper was used as a
germination substrate. The germitest paper was
moistened with distilled water (control) and with
four concentrations of sodium chloride. The volume
of water applied to the paper was 2.5 times the
weight of dry paper. The germitest paper rolls were
kept in a germination chamber at 25°C and the
number seedlings were counted 14 days after
sowing, with results expressed as a percentage of
normal seedlings (BRASIL, 2009).
First germination count (FGC): The
number of normal seedlings was counted in each
replicate five days after the start of the test. The
results were expressed as a percentage of normal
seedlings.
Cold test (CT): Four replicates of 50 seeds
for each experimental unit were uniformly
distributed on germitest paper rolls, moistened with
distilled water (control) and with four
concentrations of sodium chloride. The volume of
water applied to the paper was 2.5 times the weight
of dry paper. The germitest rolls were immediately
placed in plastic bags, which were sealed and kept
in a BOD chamber at a temperature of 10ºC ± 1ºC
for seven days (CICERO; VIEIRA, 1994). At the
end of this period, the rolls were transferred to a
germination chamber and maintained under the
same conditions as the germination test, assessing
the percentage of normal seedlings after five days.
Accelerated aging (AA): Seeds were
uniformly spread over a metal screen suspended in a
germination box containing 40 ml distilled water.
The boxes were capped and kept in BOD chamber
at 41°C for 72 h (MARCOS FILHO, 1999). Then
the seeds were germinated as for the germination
test and seedlings counted on the fifth day. The
1454
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
results were expressed as a percentage of normal
seedlings.
Seedling shoot length (SL) and root length
(RL): Four replicates of 20 seeds for each
experimental unit were crisscrossed in two rows in
the upper third of the germitest paper, moistened
with distilled water (control) and with four
concentrations of sodium chloride. The volume of
water applied to the paper was 2.5 times the weight
of dry paper. The paper rolls were kept in a
germination chamber at 25°C. The total seedling
length and the shoot length of ten randomly selected
seedlings were measured five days after sowing
using a ruler graduated in millimeters. The root
length was estimated by subtracting the shoot length
from the total seedling length. The average lengths
of shoots and roots were determined by summing
the readings of each replication and dividing by the
number of seedlings evaluated, according to the
methodology described by Nakagawa (1999).
Seedling dry weight (SDW): Shoots and
roots were separated with a scalpel, placed in paper
bags and dried in an air-circulating oven at 60°C for
72 hours. After this period, the samples were placed
to cool in a desiccator and weighed on an analytical
balance. Results are expressed in mg seedling-1
(NAKAGAWA, 1999).
The experimental data were subjected to
analysis of variance. Significant results were further
explored using "t-test" for qualitative factors and
polynomial regression analysis for quantitative
factors. Significance was set at the 5% probability
level.
RESULTS AND DISCUSSION
There was a significant interaction between
lots and amino acid salt concentration for the first
count of germination, cold test and root dry weight
(Table 1).
Table 1. Results of the first count of germination tests (FGC), cold test (CT) and root dry weight (RDW) for
two lots of rice seeds with and without amino acid treatment and subjected to different degrees of salt
stress with sodium chloride.
[NaCl] (mM) Amino acid
FCG (%) CT (%) RDW (mg)
Lot 1 Lot 2 Lot 1 Lot 2 Lot 1 Lot 2
0
With 74 Aa¹ 70 Aa 61 Aa 67 Aa 1.52 Aa 1.10 Ab
Without 71 Aa 68 Aa 59 Aa 64 Aa 1.44 Aa 1.01 Ab
25
With 72 Aa 66 Ab 57 Ab 64 Aa 1.39 Aa 1.24 Ab
Without 70 Aa 61 Bb 58 Aa 63 Aa 1.24 Ba 1.20 Aa
50
With 71 Aa 66 Aa 56 Aa 57 Aa 0.96 Ab 1.23 Aa
Without 62 Ba 55 Bb 54 Aa 55 Aa 1.08 Aa 0.95 Ba
75
With 65 Aa 65 Aa 58 Aa 55 Aa 0.88 Ba 0.89 Aa
Without 50 Ba 54 Ba 44 Bb 55 Aa 1.07 Aa 0.83 Ab
100
With 33 Ab 56 Aa 51 Aa 49 Aa 0.66 Aa 0.69 Aa
Without 23 Bb 31 Ba 27 Bb 39 Ba 0.70 Aa 0.55 Bb
C.V. (%) 6.5 8.8 9.6
1 Means followed by the same capital letter in columns within each concentration do not differ by test t (p ≤ 0.05). Means followed by
the same lowercase letter in rows for each response variable do not differ by test t (p ≤ 0.05).
For the first count of germination lot 1 had
more normal seedlings than lot 2 at a salt
concentration of 25 mM, while lot 2 had a higher
percentage of normal seedlings at the highest
concentration used. Other differences were not
significant (Table 1). Without the use of amino acid,
lot 1 had more normal seedlings at salt
concentrations of 25 and 50 mM, but at
concentrations of 75 and 100 mM lot 2 had a higher
percentage of normal seedlings. The same behavior
was observed for lot 2 at the concentrations of 25,
50, 75 and 100 mM (Table 1). These results may be
related to the activation of enzymes that promote
germination using amino acid and may favor the
best performance of the seeds during stress
(PRIYACHEM, 2014b). Lima et al. (2005), using
BRS Bojurú and IAS 12-9 Formosa (salt-tolerant)
and BRS Agrisul and BRS 6 Chui (salt-sensitive)
rice treated with sodium chloride, found a decrease
in germination in both cultivars with increasing
salinity, and concluded that salinity affected the
development of normal seedlings and decreases the
viability and vigor of seeds.
1455
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
In general seedling germination in after
treatment with cold and amino acids did not differ
between lots within each level of salinity, except at
a salt concentration of 25 mM when lot 2 had more
normal seedlings than lot 1 (Table 1). For lot 1, the
use of amino acid promoted an increase in vigor at
salt concentrations of 50, 75 and 100 mM, and for
lot 2, there was an increase in vigor only at a salt
concentration of 100 mM (Table 1). Possibly the
applied product has an anti-stress effect due to the
action of amino acids in plant metabolism.
Using amino acid on lot 1 resulted in greater
dry weight of roots at salt concentrations of 0 and 25
mM, while at 50 mM salt, lot 2 had heavier roots
(Table 1). In the treatment without amino acid, lot 1
roots were heavier at salt concentrations of 0, 75 and
100 mM. Within lot 1 root dry weight was greater
with amino acid only at a salt concentration of 25
mM. However, a salt concentration of 75 mM
without amino acid generated seedlings with heavier
root dry matter. In lot 2, treatment with amino acid
resulted in greater root dry matter at salt
concentrations of 50 and 100 mM (Table 1).
In lot 1, the proportion of normal seedlings
germinated on day five showed a quadratic
relationship with salt concentration for both amino
acid treatments (Table 2). There was an increase in
the percent normal seedlings up to concentrations of
25.74 mM in seeds treated with amino acid and to
15 mM in seeds without amino acid treatment.
Treatment with amino acid resulted in an increase of
4.9% at the point of maximum, while absence of
amino acid resulted in an increase of only 1.49%
(Table 2). This demonstrates that coating with
amino acid increased the tolerance of seeds to
salinity to a maximum tolerable salinity, but there
was a sharp drop in the percentage of normal
seedlings at greater salinity. In lot 2 treatments with
and without amino acid the relationship between
percent normal seedlings and salinity is a decreasing
linear model with reductions of 0.119% (+ amino
acid) and 0.318% (– amino acid) for each unit
increase in the salt concentration (Table 2).
Similarly, Deuner et al. (2011), working with seed
from different cowpea genotypes, found that an
increase in soil salt concentration reduced first and
final germination counts.
Increasing salinity produced similar
responses in the cold test in treatments with and
without amino acid in both batches, with a reduction
in the percent of normal seedlings of 0.078% (+
amino acid) and 0.177% (– amino acid) (lot 1), and
0.318% (+ amino acid) and 0.233% (– amino acid)
(lot 2) for every unit increase in the salt
concentration (Table 2). Treatment with amino acid
in lot 1 resulted in a less marked decrease in the
effect of increasing salinity compared to the seed of
lot 1 without amino acid.
Table 2. Regression Analysis of the first count of germination, cold test and root dry weight of two lots of rice
seeds with and without amino acid treatment and subjected to different concentrations of sodium
chloride.
Amino acid
Lot
Equation
Y = ±ax³±bx²±cx±d
P
(bix)
R² Y
Expected
First count of germination (%)
With
Lot 1 -0.0074x² + 0.381x + 71.5 * 0.94 76.4
Lot 2 -0.119x + 70.5 * 0.79 70.5
Without
Lot 1 -0.0066x² + 0.198x + 69.9 * 0.99 75.6
Lot 2 -0.318x + 69.6 * 0.83 69.6
Cold Test (%)
With
Lot 1 -0.078x + 60.35 * 0.67 60.4
Lot 2 -0.318x + 64.25 * 0.85 64.3
Without
Lot 1 -0.177x + 67.15 * 0.98 67.2
Lot 2 -0.233x + 66.90 * 0.85 66.9
Root Dry Weight (mg)
With
Lot 1 -0.0089x + 1.527 * 0.95 1.527
Lot 2 -0.0066x + 1.436 * 0.92 1.436
Without
Lot 1 -0.0001x² + 0.0068x + 1.120 * 0.94 75.8996
Lot 2 -9E-5x² + 0.0042x + 1.046 * 0.92 76.3611
*Significant at 5 % probability.
1456
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
The relationship of the root dry weight to
salinity (Table 2) decreased linearly in both lots
treated with amino acid, decreasing 0.0089 (lot 1)
and 0.0066 (lot 2) mg per plant for each unit of
increased salt concentration. In treatment without
amino acid root dry weight was related to salt
concentration in a quadratic model for both lots
(Table 2), with the point of maximum efficiency at
concentrations of 34 mM (lot 1) and 23 mM (lot 2) .
Likewise, Moraes et al. (2005) observed that bean
seedlings had small increases in dry mass at the
lower osmotic concentrations, reducing the most
negative potential.
A significant interaction between amino
acid treatment and batches of seed in germination
(Table 3) showed that lot 1 had better germination
than lot 2 only in the treatment without amino acid.
The use of amino acids in seed treatment promoted
more germination in both lots. Application of amino
acids to bean seeds showed no positive effect on
seed germination. but the seeds had greater viability
(KIKUTI; TANAKA, 2007).
Table 3. Percentage of normal seedlings obtained from germination test (G) of two lots of rice seeds with and
without amino acid treatment and subjected to different concentrations of sodium chloride.
Amino acid
G (%)
Lot 1 Lot 2
With ¹91 Aa 91 Aa
Without 87 Ba 85 Bb
C.V. (%) 2.3
1 Means followed by the same capital letter in columns within each concentration do not differ by test t (p ≤ 0.05). Means followed by
the same lowercase letter in rows for each response variable do not differ by test t (p ≤ 0.05).
There was an interaction between batches
and salt concentration in accelerated aging tests,
root length and dry weight of shoots (Table 4). Lot 1
was more vigorous than lot 2 at concentrations of 25
and 50 mM, but at concentrations of 0 and 100 mM,
lot 2 was more vigorous. Lot 1 had longer roots at a
concentration of 50 mM but lot 2 had longer roots at
zero salinity. Lot 1 had greater shoot dry mass than
lot 2 at salinities of 50, 75 and 100 mM. It should be
noted that the effects of salinity vary with species
and plant growth stage, as well as with the type,
duration and intensity of stress (LARCHER, 2000).
Table 4. Results of accelerated aging tests (AA), root length (RL) and dry weight of shoot (DWS) for two lots
of rice seeds with and without amino acid treatment and subjected to different concentrations of
sodium chloride.
[NaCl] (mM)
AA (%) RL (cm) DWS (mg)
Lot 1 Lot 2 Lot 1 Lot 2 Lot 1 Lot 2
0 ¹81 b 85 a 7.3 b 7.7 a 1.60 a 1.68 a
25 84 a 79 b 7.1 a 7.3 a 1.38 a 1.32 a
50 83 a 77 b 6.9 a 6.5 b 1.31 a 1.16 b
75 74 a 74 a 6.1 a 6.1 a 1.06 a 0.74 b
100 69 b 71 a 5.4 a 5.3 a 0.73 a 0.60 b
C.V. (%) 3.0 5.3 9.8
1Means followed by the same lowercase letter in rows for each response variable do not differ by test t (p ≤ 0.05).
Lots performed differently to increasing
salinity. Lot 1 responded to salinity in a quadratic
model with an increase in the percentage of normal
seedlings up to a salinity of 24.3 mM, while lot 2
decreased linearly with increasing salinity by
0.129% for each unit increase in salt concentration
(Table 5). Root length and dry weight of shoots
behaved similarly, with linear reduction with
increased salt concentration (Table 5). The slope of
the decline in root length differed between lots, with
reductions of 0.0194 (lot 1) and 0.0245 (lot 2) cm
for every unit increase in the salt concentration.
Similarly, shoot dry mass decreased by 0.0082 (lot
1) and 0.0109 (lot 2) mg per plant for each unit
increase in salt concentration.
1457
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
Table 5. Regression Analysis of accelerated aging test, root length and dry weight of shoots of two lots of rice
seedlings with and without amino acid treatment and subjected to different concentrations of sodium
chloride.
Batches
Equation
Y = ±ax³±bx²±cx±d
P
(bix)
R² Y
Expected
Accelerated Aging Test (%)
Lot 1 -0.0028x² + 0.1361x + 81.711 * 0.96 76.4
Lot 2 -0.129x + 83.475 * 0.95 83.5
Root Length (cm)
Lot 1 -0.0194x + 7.5158 * 0.91 7.5
Lot 2 -0.0245x + 7.8024 * 0.98 7.8
Shoot Dry Weight (mg)
Lot 1 -0.0082x + 1.6283 * 0.96 1.6283
Lot 2 -0.0109x + 1.6488 * 0.98 1.6488
*Significant at 5 % probability.
There was a significant interaction of amino
acid treatment and salt concentration for the root
length and dry weight of shoots (Table 6). There
was no difference in root length between amino acid
treatments.
Table 6. Root length (RL) and dry weight of shoot (DWS) of two lots of rice seedlings, with and without amino
acid treatment and subjected to different concentrations of sodium chloride.
NaCl (mM)
RL (cm) DWS (mg)
Amino acid
With Without With Without
0 ¹7.6 a 7.4 a 1.78 a 1.50 b
25 7.3 a 7.1 a 1.44 a 1.26 b
50 6.5 a 6.8 a 1.29 a 1.19 a
75 5.6 b 6.6 a 0.90 a 0.91 a
100 5.2 a 5.4 a 0.71 a 0.62 a
C.V. (%) 5.3 9.8
1Means followed by the same lowercase letter in rows for each response variable do not differ by test t (p ≤ 0.05).
However, treatment with amino acid
promoted shoot growth at salt concentrations of 0
and 25 mM themselves, except for 75 mM
concentration of no treatment where the amino acid
was higher (Table 6).
Both root length and dry weight of shoots
decreased linearly with increasing salt concentration
with and without amino acid (Table 7). Root length
increased by 0.0257 cm (+ amino acid) and 0.0182
cm (– amino acid) for every unit increase in salt
concentration. The negative effect of salinity on the
growth and development of plants has been
demonstrated by Torres et al. (2000) for cucumber,
Duarte et al. (2006) for wheat and Garcia et al.
(2007) for corn. A linear decrease was observed in
the dry matter of leaves with increasing salinity in
both treatments of 0.0107 (+ amino acid) and 0.0085
(– amino acid) mg for each unit increase in the salt
concentration (Table 7).
A main effect of treatment with or without
amino acid was observed in the accelerated aging
and shoot length tests (Table 8). The main effect of
salt concentration was also observed in the shoot
length variable (Table 9). Treatment with amino
acid gave higher values for both variables (Table 8).
Seedlings with greater initial growth can generate
more productive plants because of plants with high
speed emergence and early growth use
environmental resources early and therefore, usually
have a competitive advantage (GUSTAFSON et al.
2004). Albuquerque et al. (2008) found that foliar
sprays with products containing amino acids
significantly favored growth of vine cuttings over
control sprays. In turn, Light et al. (2010) obtained
an increase in seedling height compared to controls
1458
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
by weekly applications of amino acids on a lettuce
crop.
Increasing salt concentration caused a
negative effect on shoot length; for each unit
increase in salt concentration shoot length decreased
by 0.0153 cm (Table 9).
Table 7. Regression Analysis of the root length and dry weight of shoot of two lots of rice seedlings with and
without amino acid treatment and subjected to different concentrations of sodium chloride.
Amino Acid
Equation
Y = ±ax³±bx²±cx±d
P
(bix)
R² Y
Expected
Root Length (cm)
With -0.0257x + 7.728 * 0.97 7.7
Without -0.0182x + 7.590 * 0.86 7.6
Dry Weight of Shoot (mg)
With -0.0107x + 1.7575 * 0.98 1.7575
Without -0.0085x + 1.5195 * 0.97 1.5195
*Significant at 5 % probability.
Table 8. Results of the accelerated aging test (AA) and shoot length (SL) for two lots of rice seedlings with and
without amino acid treatment and subjected to different concentrations of sodium chloride.
Amino acid AA (%) SL (cm)
With 78 A¹ 2.0 A
Without 77 B 1.8 B
C.V. (%) 3.0 12.3
1Means followed by the same capital letter in columns within each concentration do not differ by test t (p ≤ 0.05).
Table 9. Regression Analysis of the shoot length of two lots of rice seedlings with and without amino acid
treatment and subjected to different concentrations of sodium chloride.
Salt Concentration
Equation
Y = ±ax³±bx²±cx±d
P
(bix)
R² Y
Expected
Shoot Length (cm)
NaCl (mM) -0.0153x + 2.6549 * 0.98 2.7
*Significant at 5 % probability.
The amino acids can be used as a tool to
assist the plants when they are under adverse
conditions, and the application via seed treatment
can stimulate root growth (LANA et al., 2009), as
well as acting in the rapid establishment of seedlings
under unfavorable conditions (CARVALHO et al.,
2013). Santos and Vieira, (2005), worked with
different doses of commercial product in seeds
treatment of Gossypium hirsutum L., and observed
an increase of leaf area percentage of the initial
emergence and growth of seedlings in proportion to
the increase in dose of the product.
Likewise, Skopelitis et al. (2006),
evaluating plant Nicotiana tabacum L. and Vitis
vinifera L. observed induction of some amino acids
when the plants were subjected to salt stress,
especially the glutamate dehydrogenase (GD), and
these factors of extreme importance, since the work
these amino acids minimizes stress conditions (LEA
et al., 2007).
The results showed that rice seeds treated
with amino acids performed better under salt stress
compared to seeds without amino acid. Amino acids
accelerate translocation in plants (RHODES;
HANDA, 1993), promoting rapid metabolism and
increasing enzyme activity reflected in N
metabolism and greater accumulation of assimilates.
This may explain why treatment with amino acid
produced better results in most of the variables
analyzed in both batches of seed. Because treatment
with amino acids improves seed performance, and
due to the difficulties in determining their modes of
1459
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
action on plants (CASTRO et al. 2008), research on
these compounds should be done to better establish
their efficiency in agricultural production.
CONCLUSION
Seed treatment with amino acids results in
better physiological performance of rice seeds when
subjected to salt stress, which affects negatively the
physiological quality of seeds.
RESUMO: O estresse salino em plantas de arroz afeta o crescimento, o desenvolvimento e a produtividade da
cultura. Sendo assim, o tratamento de sementes pode constituir uma tecnologia, para diminuir os efeitos deletérios
causados pelo estresse salino. A utilização de aminoácidos se difundiu muito, tanto na agricultura brasileira quanto em
outros países, devido aos benefícios proporcionados às plantas por meio do fornecimento de substâncias orgânicas que
resultam em maiores produtividades e conferem melhor qualidade nas diversas culturas. Nesse contexto, o objetivo desta
pesquisa foi avaliar o efeito da aplicação de aminoácidos, via tratamento de sementes, no potencial fisiológico de lotes de
sementes de arroz submetidos ao estresse salino. O delineamento experimental utilizado foi inteiramente casualizado em
esquema fatorial AxBxC (Fator A- Lote 1 e Lote 2; Fator B- Com aminoácido e sem aminoácido; Fator C- concentrações
salinas: 0, 25, 50, 75 e 100 mM), com quatro repetições. A qualidade fisiológica das sementes foi avaliada pelos testes de
germinação, primeira contagem da germinação, teste de frio, envelhecimento acelerado, comprimento da parte aérea e raiz
e massa seca da parte aérea e raiz. Conclui-se que o tratamento de sementes com aminoácidos proporciona melhor
desempenho fisiológico de sementes de arroz quando submetidas a estresse salino, que afeta negativamente a qualidade
fisiológica.
PALAVRAS-CHAVE: Oryza sativa L. Qualidade fisiológica. Recobrimento. Salinidade.
REFERENCES
AJINOMOTO FERTILIZANTES. Produza mais e melhor. Disponível em:
. Acesso em:
10 set. 2013.
ALBUQUERQUE, T. C. S.; DANTAS, B. F. Efeito da aplicação foliar de aminoácidos na qualidade de uvas
Benitaka. In: REUNIÃO BRASILEIRA DE FERTILIDADE DO SOLO E NUTRIÇÃO DE PLANTAS, 25;
REUNIÃO BRASILEIRA SOBRE MICORRIZAS, 9; SIMPÓSIO BRASILEIRO DE MICROBIOLOGIA DO
SOLO, 7; REUNIÃO BRASILEIRA DE BIOLOGIA DO SOLO, 4, 2002, Rio de Janeiro. Resumos... Rio de
Janeiro: SBCS; SBM, 2002. p. 44-46.
BAYS, R.; BAUDET, L.; HENNING, A. A.; LUCCA FILHO, O. Recobrimento de sementes de soja com
micronutrientes, fungicida e polímero. Revista Brasileira de Sementes, Pelotas, v. 29, n. 2, p. 60-67, 2007.
http://dx.doi.org/10.1590/S0101-31222007000200009
BENITEZ, L. C.; PETERS, J. A.; BACARIN, M. A.; KOPP, M. M.; DE OLIVEIRA, A. C.; DE
MAGALHÃES JUNIOR, A. M.; BRAGA, E. J. B. Tolerância à salinidade avaliada em genótipos de arroz
cultivados in vitro. Ceres, Viçosa, v. 57, n. 3, p. 330-337, 2010.
BRANDÃO, R. P. Importância dos Aminoácidos na agricultura sustentável. Informativo Bio Soja, São
Joaquim da Barra, inf. 5, p. 6-8, 2007.
BRASIL. Ministério da Agricultura, Pecuária e Abastecimento. Regras para análise de sementes. Ministério
da Agricultura, Pecuária e Abastecimento. Secretaria de Defesa Agropecuária. Brasília, DF: Mapa/ACS, 2009.
395p.
CARVALHO, T. C. D.; SILVA, S. S. D.; SILVA, R. C. D.; PANOBIANCO, M.; MÓGOR, Á. F. Influência de
bioestimulantes na germinação e desenvolvimento de plântulas de Phaseolus vulgaris sob restrição hídrica.
Revista de Ciências Agrárias, Recife, v. 36, n. 2, p. 199-205, 2013.
1460
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
CASTRO, P. R. C.; SERCILOTO, C. M.; PEREIRA, M. A.; RODRIGUES, J. L. M. Utilização de fosfitos e
potencial de aplicação dos aminoácidos na agricultura tropical. Piracicaba: ESALQ, DIBD, 2008. 71p.
(Série Produtor Rural, 38).
CASTRO, P. R. C; GONÇALVES, M. R.; CATO, S. C. Efeitos da aplicação foliar de Codamin e de
Brassinolide em feijoeiro. Revista de Agricultura, Piracicaba, v. 81, n. 1, p. 24-30, 2006.
CÍCERO, S. M.; VIEIRA, R. D. Teste de frio. In: VIEIRA, R. D.; CARVALHO, N. M. (Ed.) Testes de vigor
em sementes. Jaboticabal: FUNEP, 1994. p. 151-164.
COMPANHIA NACIONAL DE ABASTECIMENTO. Acompanhamento da safra brasileira de grãos: v.1-
Safra 2013/14, n.3- Terceiro Levantamento, dezembro 2013. Disponível em:
. Acesso em: 5 fev. 2014.
DEUNER, C.; MAIA, M. S.; DEUNER, S.; ALMEIDA, A. S.; MENEGHELLO, G. E. Viabilidade e atividade
antioxidante de sementes de genótipos de feijão-miúdo submetidos ao estresse salino. Revista Brasileira de
Sementes, Londrina, v. 33, n. 4, p. 711-720, 2011. http://dx.doi.org/10.1590/S0101-31222011000400013
DINIZ, K. A.; OLIVEIRA, J. A; GUIMARÃES, R. M.; CARVALHO, M. L. M; MACHADO, G. C.
Incorporação de microrganismos, aminoácidos, micronutrientes e reguladores de crescimento em sementes de
alface pela técnica de peliculização. Revista Brasileira de Sementes, Pelotas, v. 28, n. 3, p. 37-43, 2006.
DINIZ, K. A.; SILVA, P. A.; VEIGA, A. D.; ALVIM, P. O.; OLIVEIRA, J. A. Qualidade fisiológica e
atividade enzimática de sementes de alface revestidas com diferentes doses de micronutrientes, aminoácidos e
reguladores de crescimento. Revista Ciência Agronômica, Fortaleza, v. 38, n. 4, p. 396-400, 2007.
http://dx.doi.org/10.1590/s0101-31222006000300006
DUARTE, G. L; LOPES, N. F.; MORAES, D. M.; SILVA, R. N. Physiological quality of wheat seeds
submitted to saline stress. Revista Brasileira de Sementes, Pelotas, v. 28, n. 1, p. 122-126, 2006.
http://dx.doi.org/10.1590/S0101-31222006000100017
FLOSS, E. L.; FLOSS, L. G. Fertilizantes organo minerais de última geração: funções fisiológicas e uso na
agricultura. Revista Plantio Direto, Passso Fundo, v. 100, n. 1, p. 26-29, 2007.
GARCIA, G. O.; FERREIRA, P. A.; MIRANDA, G. V.; OLIVEIRA, F. G.; SANTOS, D. B. Índices
fisiológicos, crescimento e produção do milho irrigado com água salina. Irriga, Botucatu, v. 12, n. 3, p. 307-
325, 2007.
GUSTAFSON, D. J.; GIBSON, D. J.; NICKRENT, D. L. Competitive relationships of Andropogon gerardii
(Big Bluestem) from remnant and restored native populations and select cultivated varieties. Functional
Ecology, London, v. 18, n. 3, p. 451-457, 2004. http://dx.doi.org/10.1111/j.0269-8463.2004.00850.x
KIKUTI, H.; TANAKA, R. T. Produtividade e qualidade de sementes de feijão em função da aplicação de
aminoácidos e nutrientes. In: CONGRESSO NACIONAL DE PESQUISA DE FEIJÃO, 8, 2005, Goiânia.
Anais... Santo Anônio de Goiás: EMBRAPA, 2005. v. 2, p. 1062-1065.
LANA, A. M. Q.; LANA, R. M. Q.; GOZUEN, C. F.; BONOTTO, I. E; TREVISAN, L. R. Aplicação de
regulado¬res de crescimento na cultura do feijoeiro. Bioscience Journal, Uberlândia, v. 25, n. 1, p. 13-20,
2009.
LARCHER, W. Ecofisiologia vegetal. 1. ed. São Carlos: Rima, 2000. 531p
LEA, P. J.; SODEK, L.; PARRY, M. A. J.; SHEWRY, P. R. E; HALFORD, N. G. Asparagine in plants.
Annals of Applied Biology, v. 150, n. 1, p. 1–26, 2007. http://dx.doi.org/10.1111/j.1744-7348.2006.00104.x
1461
Physiological potential of irrigated… LEMES, E. S. et al.
Biosci. J., Uberlândia, v. 32, n. 6, p. 1452-1461, Nov./Dec. 2016
LIMA, M. G. S. Detecção de genes e expressão enzimática em cultivares de arroz (Oryza sativa L.)
crescidas sob estresse salino. 2008. 93f. Tese (Doutorado em Ciências) - Fisiologia vegetal, Departamento de
Botânica, Universidade Federal de Pelotas.
LIMA, M. G. S.; LOPES, N. F.; MORAES, D. M.; ABREU, C. M. Qualidade fisiológica de sementes de arroz
submetidas a estresse salino. Revista Brasileira de Sementes, Londrina, v. 27, n. 1, p. 54-61, 2005.
http://dx.doi.org/10.1590/S0101-31222005000100007
LUZ, J. M. Q.; OLIVEIRA, G.; QUEIROZ, A. A.; CARREON, R. Aplicação foliar de fertilizantes
organominerais em cultura de alface. Horticultura Brasileira, Brasília, v. 28, n. 3, p. 373-377, 2010.
http://dx.doi.org/10.1590/S0102-05362010000300023
MACHADO NETO, N.; CUSTÓDIO, C. C.; COSTA, P. R.; DONÁ, F. L. Deficiência hídrica induzida por
diferentes agentes osmóticos na germinação e vigor de sementes de feijão. Revista Brasileira de Sementes,
Pelotas, v. 28, n. 1, p. 142-148, 2006. http://dx.doi.org/10.1590/S0101-31222006000100020
MARCOS FILHO, J. Testes de vigor: importância e utilização. In: KRZYZANOWSKI, F. C., VIEIRA R. D.
(Eds.). Vigor de sementes: Conceitos e testes. Londrina, ABRATES, cap. 3, p. 3-24, 1999.
MORAES, G. A. F.; DE MENEZES, N. L.; PASQUALLI, L. L. Comportamento de sementes de feijão sob
diferentes potenciais osmóticos. Ciência Rural, Santa Maria, v. 35, n. 4, p. 776-780, 2005.
http://dx.doi.org/10.1590/S0103-84782005000400004
NAKAGAWA, J. Testes de vigor baseados no desempenho das plântulas. In: KRZYZANOWSKI, F. C.;
VIEIRA, R. D.; FRANÇA-NETO, J. B. (Eds.). Vigor de sementes: conceitos e testes. Londrina: ABRATES,
cap. 2, p. 9-13. 1999.
NUNES, J. C. Tratamento de semente - qualidade e fatores que podem afetar a sua performance em
laboratório. Syngenta Proteção de Cultivos Ltda. 2005. 16p.
PRIYACHEM. Ankur. Disponível em: . Acesso em: 9 fev. 2014.
2014b
PRIYACHEM. Technical e scientifc data. Amino-acids as plant nutrients for foliar spray and fertigation,
2014a.
RHODES A. S., HANDA S. 1989. Amino acid metabolism in relation to osmotic adjustment in plant cell. In:
Cherry, J. H. (Ed), Environmental stress in plants, p. 41-62. http://dx.doi.org/10.1007/978-3-642-73163-1_6
ROSSETTI, M. L. R. A célula e seus constituintes moleculares. In: ZAHA, A.; PASSAGLIA, L. M. P.;
FERREIRA, H. B. Biologia Molecular Básica. 4. ed. Porto Alegre (RS): ARTMED, Cap. 1, p. 4-14, 2012.
TORRES, S. B.; VIEIRA, E. L.; MARCOS FILHO, J. Efeitos da salinidade na germinação e no
desenvolvimento de plântulas de pepino. Revista Brasileira de Sementes, Brasília, v. 22, n. 2, p. 39-44, 2000.
http://dx.doi.org/10.17801/0101-3122/rbs.v22n2p39-44
USDA - UNITED STATES DEPARTMENT OF AGRICULTURE. Disponível em: . Acesso em: 27 mar. 2013.
VAN NGUYEN, N.; FERRERO, A. Meeting the challenges of global rice production. Paddy and Water
Environment, Japão, v. 4, n. 1, p. 1-9, 2006.