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1242 
Original Article 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1242-1248, Sept./Oct. 2017 

INITIAL GROWTH IN MAIZE IN COMPLIANCE OF AZOSPIRILLUM 
BRASILENSE INOCULATION AND NITROGEN RATES 

 
CRESCIMENTO INICIAL DO MILHO EM FUNÇÃO DA INOCULAÇÃO DE 

AZOSPIRILLUM BRASILENSE E DOSES DE NITROGÊNIO 
 

Elisa Pereira de OLIVEIRA¹; Matheus Gustavo da SILVA²; Paulo Eduardo TEODORO³ 
1. Universidade Estadual Paulista “Julio de Mesquita Filho”, Campus Botucatu, Botucatu, SP, Brasil; 2. Universidade Estadual do Mato 

Grosso do Sul, Unidade Universitária de Aquidauana, Aquidauana, MS, Brasil; 3. Universidade Federal do Mato Grosso do Sul, 
Campus de Chapadão do Sul, MS, Brasil. eduteodoro@hotmail.com 

 
ABSTRACT: Investigate the effects of the interaction between nitrogen fertilization and inoculation with 

diazotrophic bacteria becomes important, especially for maize, highly exacting in N. Thus, the aim of this study was to 
evaluate the initial growth of maize in compliance A. brasilense inoculation and nitrogen rates. The experiment was 
conducted in a greenhouse, in Mato Grosso do Sul State University, Aquidauana University Unit, between the months of 
march and April of 2014. It was used completely randomized design in a 2x4 factorial arrangement with four replications. 
The treatments consisted of the absence and presence of inoculation with A. brasilense and four levels of nitrogen 
fertilization (0, 25, 50, 100 kg ha-1 N). At 40 days after sowing the following variables were evaluated: leaf area, plant 
height, stem diameter, dry mass of shoot and of root. There was interaction between doses of nitrogen and inoculation with 
A. brasilense for most of the evaluated variables. Inoculation with A. brasilense provides improvements in the 
establishment and initial development of maize. In the presence of inoculation with A. brasilense, the development of 
maize increases linearly the administration of the nitrogen doses. 

 
KEY WORDS: Nitrogen fertilization. Diazotrophic bacteria. Inoculant. Zea Mays L. 

 
 
INTRODUCTION 

 
Maize (Zea mays L.) is a cereal of great 

economic importance in the world. Brazil is the 
third largest producer of this grain, the national 
production of maize in the harvest reached a volume 
of approximately 81.5 million tons (CONAB, 2014). 
The economic importance of maize is characterized 
by its use diversity, ranging from human and animal 
feed to high technology industries, such asthe 
ethanol production ones (NERI et al., 2005; 
TEODORO et al., 2015). 

Maize is a demanding crop when it comes to 
soil fertility, given the fact that it requires a great 
amount of nitrogen (N), it represents  one of the 
highest costs to the producers due to the  high 
demand for nitrogen fertilizers (MALAVOLTA, 
2006). Although N is present in the atmosphere, it is 
not available in an assimilable form to the plants. 
Thus, its fixation in the soil can occur by means of 
electric discharges and industrial or biological 
processes (CARMO et al., 2012). Among these 
processes, the biological nitrogen fixation (BNF) 
accounts for about 60% of all N accumulated by the 
plants, being of great support for the increased yield, 
in addition to being an ecological and more 
economical alternative to the nitrogen fertilizers 
(BODDEY et al., 2001). 

Bacteria from the 5 genus can be inoculated 
in the plants of agronomic interest, stimulating their 
growth throught multiple mechanisms, which 
include phytohormone synthesis,  nitrogen nutrition 
improvement, stress mitigation and the biological 
control of the pathogenic microbiota. (BASHAN; 
BASHAN, 2010; MORAIS et al., 2016). 
Azospirillum genus (gram-negative, aerobic or 
microaerophilic bacteria) belongs to the 
Alfaproteobacterias class, Rhodospirillaceae family, 
and it is currently possible to find more than 200 of 
its variations in the gene bank (QUADROS et al., 
2014). 

Nitrogen fixation in the plant during the 
plant-bacteria association is a process in which 
bacteria only provide fixed nitrogen if sources of 
carbon and energy are sufficiently available 
(CHUBATSU et al., 2012). Thus, it is important to 
investigate the interaction effects between nitrogen 
fertilization and inoculation with diazotrophic 
bacteria, especially for the maize crop, which 
presents high demands for N. In this sense, we 
emphasized the hypothesis on the extent to which it 
would be feasible to substitute mineral nitrogen by 
the Azospirillum brasilense inoculation. Thus, this 
study aimed to verify the initial maize growth in 
compliance with the A. brasilense inoculation and 
nitrogen rates. 

 

Received: 06/12/16 
Accepted: 05/05/17 



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Biosci. J., Uberlândia, v. 33, n. 5, p. 1242-1248, Sept./Oct. 2017 

MATERIAL AND METHODS 
 
Trial was carried out in greenhouse at State 

University of Mato Grosso do Sul, Unit of 
Aquidauana, from March to April, 2014. Region 
climate is classified according to Köppen’s 
classification as Aw, tropical sub-humid, with rainy 
summer and dry winter, average annual rainfall of 
1,200 mm and maximum and minimum 
temperatures of 33 and 19 ºC, respectively. Region 
soil was classified as Red Ultisol dystrophic sand 
texture. 

Agricultural greenhouse where the trial was 
carried out has a galvanized arc structure, chapel 
type, with a low-density polyethylene film (LDPE) 
of 150 microns thickness, zenith aperture and 
thermo-reflective screen (50% shading), having 6.4 
m wide by 18 m long, with 4 m height under. 

A completely randomized design was used 
in a 2x4 factorial scheme, with four replications. 
The treatments consisted of combining absence and 
presence of A. brasilense inoculation and four 
nitrogen fertilizer rates (0; 25; 50; 100 kg ha-1 of N). 

The plants were conducted in plastic 
containers with a capacity of 5 L previously 
disinfected with solution containing 40% alcohol + 
10% formaldehyde + 20% sodium hypochlorite and 
air dried. Soil for filling the pots was collected and 
later air-dried and sifted for packaging in the pots. 
Soil chemical analysis was performed, from which 
singe samples were taken from the 0-20 cm layer, 
forming the composite sample that was sent to the 
laboratory. 

The soil showed the following chemical 
characteristics: pH (CaCl2) = 4.3; OM = 3 g dm

-3; P 
= 0 mg dm-3; Ca = 5 mmolc dm-3, Mg = 4 mmolc 
dm-3, K = 0,8 mmolc dm

-3, Al = 14 mmolc dm
-3, 

H+Al = 32 mmolc dm
-3, and CEC= 42 mmolc dm

-3. 
Dolomitic limestone (28% CaO, 20% MgO and 
75% relative total neutralizing power – RTNP) was 
applied to raise base saturation to 60% (2.11 t ha-1). 
So that there was chemical reaction in the soil, it 
was moistened to the field capacity and conditioned 
under plastic canvas for 20 days. Fertilization was 
carried out according to the soil analysis using 120 
kg ha-1 P2O5, 180 kg ha

-1 K2O (RAIJ et al., 1996) 
and nitrogen fertilization according to treatments 
using urea at sowing. 

Maize seeds were inoculated with the 
commercial product AZOMAX, manufactured by 
Novozymes company, containing ABV-5 and ABV-
6 strains from A. brasilense bacterium at a minimum 
concentration of 3x108 viable cells mL-1. For each 
hybrid, the manufacturer's recommended dose 

equivalent to 150 mL of the commercial inoculant 
was applied to 60,000 seeds. 

We used in this trial the Maximus single 
hybrid, manufactured by the Syngenta company. 
Seeding was done with four seeds per pot, placed at 
3 cm deep. Thinning was performed 10 days after 
sowing (DAS), maintaining two plants per pot. At 
10 days after emergence (DAE), due to the low level 
of phosphorus in the soil (0 mg dm-3) fertilization 
with monobasic potassium phosphate solution 
(KH2PO4) was carried out at rate of 658.5 mg mL

-1 
by applying 100 mL per pot (equivalent to 1,317 kg 
ha-1). 

Evaluations were carried out at 40 DAS (V8 
stage in which the number of grain rows), 
determining the plant height using graduated ruler 
for measuring from the ground base until the last 
completely developed leaf insertion; stem diameter, 
measured in the neck region using a digital caliper; 
leaf area, estimated by measuring length and width 
of the +3 leaf, according to the method described by 
Pereira (1987): LA = L x W x 0.75, where LA is 
leaf area; L is the leaf +3 length; W is the width +3 
length; and 0.75 is the correction factor for leaf area 
of the crop. 

The plants were removed from the pots and 
partitioned into shoot and root system. Root system 
was washed in running water, using a fine mesh 
sieve to avoid finer root losses. Leaves, stems and 
roots were separated, packed in paper bags and 
dried in an oven with circulation at 65ºC for 72 
hours, and then the dry mass of shoot and root were 
recorded. 

Analyzed variables were initially submitted 
to the Shapiro-Wilk and Bartlett tests to verify the 
normality of the residues and to test the 
homogeneity between the variances, respectively. 
Subsequently, data were submitted to analysis of 
variance, the qualitative factor (absence and 
presence of the inoculation) being submitted to the 
comparison of means by the Tukey test and the 
quantitative (N rates) to the polynomial regression 
analysis. The best adjusted equation was chosen 
according to the coefficient of determination and the 
regression coefficients significance, tested by the t-
test corrected based on the residues of the analysis 
of variance. All the analyzes were performed using 
Sisvar statistical software (FERREIRA, 2011). 

 
RESULTS AND DISCUSSION 

 
There was significant interaction (p<0.01) 

between A. brasilense inoculation (I) and nitrogen 
rates (N) on all variables evaluated, except for the 



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Biosci. J., Uberlândia, v. 33, n. 5, p. 1242-1248, Sept./Oct. 2017 

stem diameter, which was influenced by the isolated factors (Table 1). 
 
Table 1. Values of F calculated for the variables plant height (PH), stem diameter (SD), leaf length (LL), leaf 

width (LW), number of leaves (NL), leaf area (LA), dry mass of shoot (DMS) and dry mass of roots 
(DMR) in compliance of A. brasilense inoculation (I) and nitrogen rates (N). 

Variable Inoculation Nitrogen I x N CV (%) 
LA 32.02* 35.94* 9.52* 16.23 
PH 10.72* 12.52* 5.73* 11.19 
SD 10.42* 17.91* 2.16ns 11.86 
DMS 69.20* 65.40* 18.69* 18.04 
DMR 32.99* 37.95* 7.11* 17.14 
ns, *, **: not significant, significant at 5 and 1% probability by the F test, respectively; CV: coefficient of variation. 
 

A. brasilense inoculation provided the 
highest values for leaf area (Table 2) and plant 
height (Table 3) only when combined with the rate 
100 kg ha-1 of N. In the absence of inoculation, there 
was a quadratic adjustment in response to N rates 

(with maximum point obtained with the 
approximate rate 60 kg ha-1 of N), while in the 
presence of inoculation there was a linear increase 
in plant height in both variables. 

 
Table 2. Unfolding the significant interaction between nitrogen rates and A. brasilense inoculation for leaf area 

(cm²) in maize. 

Inoculation 
Nitrogen Rates (kg ha-1) 

Equation R² 
0 25 50 100 

Absence 61.7 109.9 125.0 114.3 b Y = 63.26 + 2.093x - 0.0160x² 0.987 
Presence 69.1 137.3 145.8 218.1 a Y = 81.90 + 1.386x 0.943 
Averages followed by different letters at each nitrogen rate differ from each other by the Tukey test at 5% probability. 
 
Table 3. Unfolding the significant interaction between nitrogen rates and A. brasilense inoculation for plant 

height (cm) in maize. 

Inoculation 
Nitrogen Rates (kg ha-1) 

Equation R² 
0 25 50 100 

Absence 11.3 13.9 14.6 13.3 b Y = 11.41 + 0.118x - 0.0010x² 0.981 
Presence 11.9 14.0 15.8 19.1 a Y = 12.00 + 0.072x 0.998 
Averages followed by different letters at each nitrogen rate differ from each other by the Tukey test at 5% probability. 
 

Zemrany et al. (2006), Ramos et al. (2010), 
Hungria et al. (2010), Novakowisk et al. (2011), 
Kappes et al. (2013) and Quadros et al. (2014) 
observed an increase in the plant height in maize in 
response to the A. brasilense inoculation under 
different N rates. This may have occurred because 
there is a higher plant hormones production in the 
presence of A. brasilense, such as gibberellin (GA3 
and GA1), which together with the use of N, 
participates directly in the cell division and 
expansion and in the photosynthetic process 
(RIBAUDO et al., 2001; BASHAN et al., 2004). 

The increase of 14% in the stem diameter of 
maize plants, provided by the A. brasilense 
inoculation is important because it minimizes 
possible situations of stress, since this organ is a 
source of carbohydrate reserves and lodging (Table 
4). Ramos et al. (2010) and Hungria et al. (2010) 
also observed an increase of this variable in 
response to the A. brasilense inoculation. However, 
Repke et al. (2013) did not observe any inoculation 
influence  on the maize development, including their  
stem diameter. 

 
Table 4. Mean values for stem diameter (cm) in maize plants in compliance of absence and presence of A. 

brasilense inoculation and regression equation in response to nitrogen rates. 
Inoculation Stem diameter (cm) Equation R² 
Absence 8.08 b Y = 5.01 + 0.016x 0.891 
Presence 9.22 a Y = 7.18 + 0.033x 0.929 
Averages followed by different letters at each nitrogen rate differ from each other by the Tukey test at 5% probability. 

 



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There was a linear increase in the stem 
diameter in response to N rates (Table 4), possibly 
because this nutrient increases CO2 assimilation and 
chlorophyll synthesis, providing greater 
photosynthetic capacity to plants and greater 
accumulation of carbohydrates, which are stored in 
this organ (CASTRO et al., 2008). 

Under absence of N fertilization, there was 
no difference between the treatments for the 

production of dry mass of shoot (Table 5) and roots 
(Table 6). However, in the other rates A. brasilense 
inoculation provided the highest values for both 
variables. According to Ribaudo et al. (2001) and 
Quadro et al. (2014), this occurs because bacteria 
from the Azospirillum genus use N from nitrogen 
fertilization to assimilate carbon and multiply 
themselves faster, increasing the inoculation effects. 

 
Table 5. Unfolding the significant interaction between nitrogen rates and A. brasilense inoculation for dry mass 

of shoot (g) in maize. 

Inoculation 
Nitrogen Rates (kg ha-1) 

Equation R² 
0 25 50 100 

Absence 1.30 3.22 b 4.18 b 3.72 b Y = 1.31 + 0.092x - 0.0007x² 0.999 
Presence 1.48 4.50 a 6.13 a 9.29 a Y = 2.05 + 0.075x 0.974 
Averages followed by different letters at each nitrogen rate differ from each other by the Tukey test at 5% probability. 
 
Table 6. Unfolding the significant interaction between nitrogen rates and A. brasilense inoculation for dry mass 

of root (g) in maize. 

Inoculation 
Nitrogen Rates (kg ha-1) 

Equation R² 
0 25 50 100 

Absence 2.44 5.72 b 8.15 b 9.67 b Y = 2.42 + 0.155x - 0.0008x² 0.999 
Presence 3.10 8.83 a 12.78 a 21.04 a Y = 3.74 + 0.175x 0.994 
Averages followed by different letters at each nitrogen rate differ from each other by the Tukey test at 5% probability. 
 

Under the absence of inoculation there was 
a quadratic adjustment in response to N rates (with 
the maximum point obtained with the approximate 
dose of 65 to 95 kg ha-1 of N for the variable dry 
mass of shoot and root, respectively), while under 
the presence of inoculation there was a linear 
increase in the shoot (Table 5) and the  root (Table 
6) dry mass. Stancheva et al. (1992) stated that the 
increased dry mass of maize plants inoculated with 
A. brasilense occurs mainly under the presence of 
high N rates, which is related to the increased 
activity of photosynthetic enzymes and assimilation 
of this nutrient. 

Reis Júnior et al. (2008), Hungria et al. 
(2010) and Quadros et al. (2014) have also observed 
an increase in dry mass of shoot and root of maize 
plants with A. brasilense inoculation. Bashan et al. 
(2004) pointed out that the plant hormones, 
especially indole acetic acid (IAA), excreted by 
bacteria from Azospirillum genus, play an essential 
role in promoting plant growth. Hartmann et al. 
(1983), Gopalswamy and Asekaran (1988) and 
Salamone and Dobereiner (1996) verified that maize 
seedlings with A. brasilense inoculation showed an 

increased in the number of root hairs, shapes and it 
also developed  numerous primary and secondary 
lateral roots, which increase the nutrient uptake 
from the soil solution, favoring its development.  

It is estimated that the use of inoculants 
containing selected strains of A. brasilense may save 
approximately US$ 2 billion in chemical fertilizers, 
allowing reduction in transport costs, and leading to 
a reduction in pollution resulting from the 
production and use of N-fertilizers (HUNGRIA et 
al., 2010; COSTA et al., 2015).  This effect may be 
beneficial to the crop during periods of water 
deficit, since maize is highly demanding in water 
and the increased specific root surface area allows a 
greater capacity of water and soil nutrients uptake.  

 
CONCLUSIONS 
 

Azospirillum brasilense inoculation 
provides improvements in the maize establishment 
and early development.  

In the presence of Azospirillum brasilense 
inoculation, the development of maize increases 
linearly as a function of the nitrogen doses. 

 
 
RESUMO: Investigar os efeitos da interação entre adubação nitrogenada e inoculação com bactérias 

diazotróficas tornou-se importante, sobretudo para a cultura do milho, altamente exigente em N. Assim, o objetivo deste 
trabalho foi verificar o crescimento inicial do milho em função de inoculação A. brasilense e doses de nitrogênio. O 



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Biosci. J., Uberlândia, v. 33, n. 5, p. 1242-1248, Sept./Oct. 2017 

experimento foi desenvolvido em estufa agrícola, na Universidade Estadual de Mato Grosso do Sul, Unidade Universitária 
de Aquidauana, entre os meses de março a abril de 2014. Utilizou-se delineamento experimental inteiramente casualizado 
em esquema fatorial 2x4, com quatro repetições. Os tratamentos constaram da combinação da ausência e presença de 
inoculação com A. brasilense e quatro níveis de adubação nitrogenada (0; 25; 50; 100 kg ha-1 de N). Aos 40 dias após a 
semeadura foram avaliadas as seguintes variáveis: área foliar, altura de plantas, diâmetro do colmo, massa seca da parte 
aérea e massa seca das raízes. Houve interação entre doses de nitrogênio e inoculação com A. brasilense  para a maioria 
das variáveis avaliadas. A inoculação com A. brasilense proporciona melhorias no estabelecimento e no desenvolvimento 
inicial do milho. Na presença de inoculação com A. brasilense, o desenvolvimento de milho aumenta linearmente a função 
das doses de nitrogênio. 

 
PALAVRAS-CHAVE: Adubação nitrogenada. Bactérias diazotróficas. Inoculante. Zea mays L. 

 
 
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