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1062 
Original Article 

Biosci. J., Uberlândia, v. 31, n. 4, p. 1062-1070, July/Aug. 2015 

MYCORRHIZATION STIMULANT BASED IN FORMONONETIN 
ASSOCIATED TO FUNGICIDE AND DOSES OF PHOSPHORUS IN SOYBEAN 

IN THE CERRADO 
 

ESTIMULANTE DE MICORRIZAÇÃO A BASE DE FORMONONETINA ASSOCIADO 
À FUNGICIDA E DOSES DE FÓSFORO EM SOJA NO CERRADO 

 

Meire Aparecida Silvestrini CORDEIRO
1
; Dorotéia Alves FERREIRA

2
;  

Helder Barbosa PAULINO
3
; Claudio Roberto Fonseca SOUZA

4
; José Oswaldo SIQUEIRA

5
; 

Marco Aurélio Carbone CARNEIRO
6
 

1. Professora Adjunta, Universidade Federal de Mato Grosso do Sul, Chapadão do Sul, MS, Brasil. meire.cordeiro@ufms.br;  
2. Doutoranda do Programa de Pós-Graduação em Ciência do Solo da Escola Superior Luiz de Queiroz, Departamento de Ciência do 
Solo, Universidade de São Paulo, Piracicaba, SP, Brasil; 3. Professor Associado, Universidade Federal de Goiás, Regional de Jataí, 

Laboratório de Solos, Jataí, GO, Brasil; 4. Professor Adjunto, Departamento de Microbiologia, Imunologia e Parasitologia, Universidade 
Federal de Santa Catarina, Florianópolis, SC, Brasil;5. Professor Emérito, Departamento de Ciência do Solo, Universidade Federal de 
Lavras, Lavras, MG, Brasil e Instituto Tecnológico Vale, Belém, PA, Brasil. Bolsistas do CNPq; 6. Professor Associado, Departamento 

de Ciência do Solo, Universidade Federal de Lavras, Lavras, MG, Brasil. Bolsista do CNPq. 
 
ABSTRACT: Arbuscular mycorrhizal fungi (AMF) are obligatory biotrophics, which complicates the 

feasibility of producing inoculants. Thus, the discovery of substances capable of stimulating mycorrhizal colonization,  
like the isoflavone formononetin emerges as a promising alternative to explore the benefits of AMF native soil in extensive 
crops system. The aim  of this study was evaluate the application of the isoflavone formononetin (7-hydroxy-4'-methoxy 
isoflavone) andfungicide  via seed in Cerrado soil in no-tillage system and fertilization with two doses of phosphorus in 
soybean under field and controlled conditions. In the field experiment the treatments were three levels of formononetin (0, 
0.5 and 1.0 mg Formononetin seed-1) in the absence and presence of fungicide (Carbendazim + Thiram commercial mix) 
applied to seeds  with two doses of phosphorus (100 % and 33% of the recommended fertilization). The study was 
conducted until the maturation of soybeans. The greenhouse conditions experiment was implemented with the same 
treatments used in the field research  and the flowering stage of the soybean plant was simulated water stress during  10 
days, returning to normal irrigation until to harvest the soybean grain. Applying of formononetin stimulated the increased 
of mycorrhizal colonization, number of nodules, vegetative growth and soybean production in the greenhouse. In the field 
research the treatments  contributed to attenuate the negative effect of the fungicide Carbendazim + Thiram in soybean 
reflecting increased soybean production and adequate supply of soil phosphorus besides  high density of propagules of 
natives AMF that contributed to reduce the benefits of stimulating mycorrhizal (formononetin) in this research. 
 

KEYWORDS: Isoflavone. Mycorrhizal fungi. Mycorrhizal colonization. Glycine max (L) Merril. Hydric stress. 
 
INTRODUCTION 
 

The arbuscular mycorrhizal fungi (AMFs) 
are obligatory biotrophics, belonging to the 
Glomeromycota phylum (SCHÜSSLER et al., 
2001), which colonize the root of the majority of the 
vascular plants, forming mutualistic symbiosis, that 
provides many benefits and increased production of 
the colonized plants (MOREIRA; SIQUEIRA, 
2006). These benefits are of great interest for 
legumes, mainly for soybean, especially when 
grown in tropical soils such as the Cerrado of Brazil, 
which have low availability and high fixation of P 
(YAMADA; ABDALLA, 2004). Mycorrhizal  
plants have greater development, favored nutrition, 
increased reclamation of fertilizer applied, also they 
are more tolerant to different types of biotic stresses 
(pests and diseases) and abiotic, such as water 
deficit (BETHLENFALVAY et al., 1990; FOLLI-

PEREIRA et al., 2012). This symbiosis between 
AMF and plant does not replace the phosphorus 
fertilization, however, it increases the efficiency of 
plant uptake of soil phosphorus in natural or added 
conditions, which makes it extremely important for 
Cerrado soils (CORDEIRO et al., 2005; FERREIRA 
et al., 2012). 

The use of these fungi in annual crops like 
soybean, is limited due he  availability and technical 
and economic viability of AMF inoculum 
production on a large scale,  once these fungi are 
obligatory biotrophics (MOREIRA; SIQUEIRA, 
2006). The discovery of substances able to stimulate 
mycorrhizal colonization,  like the isoflavonoid 
formononetin (NAIR et al., 1991), appears as a 
promising alternative to exploit the benefits of 
native AMF in extensive crops system (SIQUEIRA 
et al., 2002).  

Commercial products formulated based in 

Received: 09/04/14 
Accepted: 15/10/14 



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Mycorrhization stimulant…  CORDEIRO, M. A. S. et al. 

Biosci. J., Uberlândia, v. 31, n. 4, p. 1062-1070, July/Aug. 2015 

formononetin have been used in some countries 
such as  United States, Philippines, Japan, South 
Africa, Colombia and Canada, but not  
commercialized in Brazil (PHC, 2014). Several in 
vitro studies showed that formononetin is the main 
bioactive compound that works by stimulating the 
growth of assimbiotic AMF spores (BAPTISTA; 
SIQUEIRA, 1994; ROMERO; SIQUEIRA, 1996) 
and is also effective in increasing the growth of 
different plants in various regions the world, 
including Brazil (DAVIES-JUNIOR et al., 2005; 
NAIR et al., 1999; NOVAIS; SIQUEIRA, 2009; 
SIQUEIRA et al., 1992), but this type of work under 
field conditions and  grain production in the Cerrado 
region in Brazil were not found.. 

In soybean crop are commonly employed 
treatments before  to sowing, including the use of 
micronutrients, inoculation with nitrogen fixing 
bacteria and specific fungicides. The latter has 
become an essential practice to ensure the 
establishment of culture and high production due the 
increase of the phytosanitary problems (HENNING 
et al., 2010). Among the most commonly used 
fungicides for the control of soil borne pathogens in 
soybean seed treatment, stands out, the commercial 
mixture Carbendazim + Thiram (EMBRAPA, 2006). 
The Carbendazim, which is of the group of 
benzimidazoles, 2 - (methoxy-carbamoyl) 
benzimidazole-(Carbendazin) has systemic action 
on soil pathogens, and Thiram chemical group 
dimethyldithiocarbamate, tetramethylthiuram 
disulfide (Tiram) considered a contact fungicide. 
These products are considered toxic to AMF, which 
may compromise the establishment of symbiosis 
and its benefits for soybean crop (IPSILANTIS et 
al., 2012; O'CONNOR et al., 2002; SCHREINER; 
BETHLENFALVAY, 1997). Thus, the application of 
the mycorrhizal stimulant product based on 
synthetic formononetin, capable of accelerating the 
process of root colonization, associated to the seed 
treatment with fungicides process, can minimize the 
harmful effects of these pesticides to the plant, but 
needs to be evaluation with field experiments. 

Therefore, the aim of this study was to 
evaluate the effects of the isoflavonoid 
formononetin (7-hydroxy-4'-methoxy-isoflavone) 
and fungicide applications in the seeds on 
mycorrhizal colonization and productivity in 
soybean crop in the Cerrado soil in tillage system 
with different doses of phosphorus in field and 
greenhouse system.  

 
MATERIAL AND METHODS 

 
This study consisted of two experiments, 

one conducted in  field and the other in  greenhouse 
conditions. The field research was conducted in 
October 2006 till February 2007 in  experimental 
area of the Jatai Reginal of the Federal University of 
Goias, defined by the coordinates 17° 53 'S and 51° 
43' W. The climate of the region according to the 
Köpen classification is Cw type, mesothermal, this 
time , September to February, the rainfall was 
1380,3 mm and with an average temperature of 24 
°C. The precipitation and temperature data were 
provided by the Meteorological Station of the 
Federal University of Goias/Regional Jatai.  

The soil of the area was classified as Latosol 
Red with slightly wavy relief , whose chemical and 
textural characteristics were: pH H2O - 6.4, organic 
matter - 33.1 g kg-1, P - 12.9 mg dm-3; K - 135 mg 
dm-3, Ca - 740 mg dm-3, Mg - 158 mg dm-3, Al - 2.7 
mg dm-3, H + Al - 411 mg dm-3; sand - 570 g kg-1, 
silt - 130 g kg-1 and clay - 300 g kg-1. 

The experimental field has about 50 ha and  
during 10 years, the no tillage system has been used 
in a succession of soybeans  crop and corn or 
sorghum as  second crops. In the 2005/2006 harvest, 
soybean was sown in October 2005, applying 2 kg 
of nitrogen ha-1 (urea), 60 kg ha-1 P2O5 (triple 
superphosphate) and 40 kg ha-1 K2O (chloride 
potassium), held in February 2006 the sorghum 
sowing, harvested in July/2006. In September 2006 
the experimental area was desiccated using 4 L ha-1 
of glyphosate, and the remaining amount of straw 
was 7.7 Mg ha-1 uniformly distributed over the 
whole  area. 

Before the implementation of the 
experiment, samples were collected to assess the 
density of spores and AMF species present in the 
area (GERDEMANN; NICHOLSON, 1963), found 
193 spores per 50 mL (3,8 spores mL-1  ± 0,4) being 
the predominant species were Acaulospora 
scrobiculata, Gigaspora margarita and Glomus sp. 

The experiment consisted of a factorial 
scheme 3 x 2 x 2 given three doses of formononetin, 
presence and absence of fungicide via soybean seed 
and two P doses (100 % and 33% of the 
recommended dose). The experimental design was a 
randomized block design with five replicates . Each 
plot had eight rows of 10 m long with row spacing 
of 0.45 m (area of 36 m2), being the useful plot for 
evaluations constituted of four rows of 8 m in length 
(area of 14.4 m2), with seeding rate of 20 seeds m-1. 
The stimulating product of mycorrhization (7-
hydroxy-4'-methoxy-isoflavone, Mycoform®) called 
formononetin was inoculated  in the seeds at 
concentrations of 0 (no inoculation), 0.5 mg seed-1  
and 1.0 mg seed-1 and being this last dose 
recommended by the company Plant Health Care 



1064 
Mycorrhization stimulant…  CORDEIRO, M. A. S. et al. 

Biosci. J., Uberlândia, v. 31, n. 4, p. 1062-1070, July/Aug. 2015 

(PHC), INC., Pittsburgh, USA, supplier of the 
product. 

The fungicide used in the seed treatment was 
the commercial mixture Carbendazim + Thiram 
(Protreat/BASF) in  recommended dose of 200 mL 
in 100 kg-1 of seeds, respectively. The concentration 
used was equivalent to 30 + 70 g Carbendazim + 
Thiram, respectively, to 100 kg of seed following 
the recommendation of this product to  soybean 
crop. 

The doses related to phosphate fertilizer 
were determined based on soil analysis (P-12.9 mg 
dm-3 and 300 g kg-1 clay) according  the 
recommendations for the Cerrado region by  Souza 
and Lobato (2002). Thus, the recommended dose 
(100 %) involved the maintenance fertilization, 
corresponding to 60 kg ha-1 P2O5 and with the 
intention to use the ability of AMF to absorb 
phosphorus from the soil, 33% of the recommended 
dose was used (20 kg ha-1 P2O5). The fertilizer was 
applied in the furrow at the time of planting, using 
as source simple superphosphate (18 % P2O5). The 
soybean variety used was the conventional A7001, 
of the company Nidera Seeds. Upon seeding, the 
fertilization with potassium using 69 kg ha-1 of KCl 
was performed, equivalent to 40 kg ha-1 K2O, for all 
plots as recommended by EMBRAPA (2006). 

The seeds were inoculated with nitrogen 
fixing bacteria using commercial inoculant 
containing Bradyrhizobium elkanii, SEMIA strains 
587 and 5019 in  aqueous liquid medium with a 
minimum 1.5 x 109 bacteria mL-1. In all the seeds 
were also applied the micronutrients cobalt, 
molybdenum and zinc in the concentrations of 0.005 
mL, 0.005 mL and 0,15 mL per kg of seeds and 
lastly the treatment with insecticide (Fipronil) in  
dosage of 200 mL per 100 kg of seeds was 
performed. 

During the experiment the weeds were 
sprayed with herbicides Chlorimuron ethyl (30 g ha-
1) and Lactofen (300 mL ha-1), for the control of 
insects Cerotoma sp., Anticarcia gemmatalis and 
Nezara viridula the insecticides Methamidophos 
(300 g ha-1) and Cypermethrin (80 mL h-1) were 
used and was also applied the fungicide 
Estrubilurina (200 mL ha-1) to prevent against the 
fungus Phakopsora pachirizi. 

The assessment of mycorrhizal colonization 
was performed by sampling 20 plants per plot, taken 
with the aid of a shovel to remove the roots, being 
determined the colonization rate at 15 days after 
germination (DAG), stage V3 with third node, 
second trifoliate leaves, at 45 DAG, R2 stage full 
bloom and 60 DAG stage R5.4 50-75% of the well 
grained pods. Approximately 1 g of the fine roots 

were removed, washed, clarified and then was held 
the staining with trypan blue according to Phillips 
and Haymann (1970). To determine the percentage 
of mycorrhizal colonization of the roots, the method 
of gridded plate according to Giovannetti and Mosse 
(1980) and the stereoscope microscope observation 
(40 x) were used. 

The number of nodules was assessed at 45 
DAG, coinciding with the R2 stage of soybean, 
being 20 plants per plot collected randomly with the 
aid of a shovel to remove the roots containing 
rhizosphere soil on a sieve, seeking the removal of 
nodules that were subsequently counted. 
 Of the plants sampled for evaluation of 
mycorrhization and nodulation (45 DAG) the third 
and fourth trifoliate leaves with stems were removed 
to assess the nutritional status of the plants. The 
samples were placed in paper bags and dried in an 
oven with forced air circulation at 70°C. Upon 
reaching constant weight, samples were removed 
from the oven, ground into a Willey mill and then 
was held the nitropercloric digestion to determine P 
(colorimetric), K (flame photometry), Ca, Mg, Cu, 
Fe, Mn (atomic absorption spectrophotometry) 
following the methodology described by Malavolta 
et al. (1997). The concentrations of N were 
determined by the Kjeldahl method.  

To assess the effects of the treatments on the 
development and production of soybeans, the 
following determinations were performed: plant 
height (cm), number of pods per plant (pods plant-1), 
100 grain mass (g) and grain yield (kg m-2).  

The research  in the greenhouse consisted of 
the same treatments deployed in the field (factorial 
scheme 3 x 2 x 2), and the experimental design was 
completely randomized (CRD) with five replicates, 
totaling 60 vessels . The soil was collected in the 
same area of the field experiment in the 0-20 cm 
layer, also sieved (2 mm) and placed in vases with a 
capacity of 7 kg of soil until planting time. 
Considering the field experiment  was utilized the 
same fertilizer  the amount calculated according to 
the soil for  each vessel  weight being applied at 
sowing time. In each vessel  eight seeds were 
planted, performing the thinning, allowing the 
growth of four soybean plants per vessel. Irrigation 
was carried out by weighing every two days to 
maintain 60 % of the total pore volume occupied by 
water. 

At 60 DAG in full bloom, the plants were 
subjected to water stress by interrupting the supply 
of water, simulating a hydric stress like veranico, 
common in this region, keeping the humidity 
between 23-25 % (weight basis) through two daily 
weighings for 10 days, and the permanent wilting 



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Mycorrhization stimulant…  CORDEIRO, M. A. S. et al. 

Biosci. J., Uberlândia, v. 31, n. 4, p. 1062-1070, July/Aug. 2015 

point for this soil was obtained in 20% humidity 
(weight basis), details on Carducci et al. (2011). 
After this period, adequate supply of water was 
restored to harvest the test to 100 DAG. Plants were 
harvested from the vessels  and determined the 
mycorrhizal colonization, grain yield vase-1, height 
(cm), number of pods plant-1 and weight of 50 
grains (g). 

All data were subjected to analysis of 
variance and to test the SISVAR statistical software 
version 4.3 (FERREIRA, 2008), with the original 
data of mycorrhizal colonization were transformed 
using arcsine (x/100)0.5 and the data of spores 
amount, number of nodules and number of pods, 
processed by the equation (x + 0.5)0.5 . 
 
 

RESULTS AND DISCUSSION 
 
In greenhouse research there was a 

significant effect (p≤0.05) only with the application 
of formononetin. The formononetin increased 
mycorrhizal colonization by mycorrhizal fungi 
(AMF) natives contributed to increases of 4% in 
plant height, 14% in the number of pods per plant 
and 11 % in grain yield (Table 1). This stimulating 
effect agrees with several studies, which showed 
that formononetin application acts to accelerate the 
germination of spores of AMF colonization and 
increase in soybean roots (BAPTISTA; SIQUEIRA, 
1994; PAULA; SIQUEIRA, 1990; SILVA-
JUNIOR; SIQUEIRA, 1997), due to these benefits 
for the plant, the fomononetina is already released in 
several countries (PHC, 2014)  

 
Table 1. Effect of formononetin on the percentage of mycorrhizal colonization, production and vegetative 

parameters studied in greenhouse research. 
Formononetin  Mycorrhizal 

colonization 
Height Mass of 50 

seeds 
Pods Production 

mg/seed % cm g N° plant-1 g vase-1 

0 39 b 76,9 b 7,21 b 14 b 12,82 b 
0,5 47 a 79,9 a 7,34 b 18 a 14,24 a 
1,0 54 a 81,7 a 8,08 a 16 ab 13,14 ab 
CV % 10 8 9 9 12 

Means followed by the same minuscule letter in the column do not differ by Tukey test at 5% of probability. 
 
The availability of water in the soil is 

important at different stages of soybean 
development, specifically in the flowering/filling 
stage when the water deficit causes losses in grain 
yield (CONFALONE; DUJMOVICH, 1999). In this 
sense, processes that ensure greater soil exploration 
by roots and hyphae of AMF can contribute to 
reducing the adverse effects of lack of water for the 
crop. The results of this study indicate that the 
application of formononetin increase colonization 
and this decrease  the effect of water stress. This is 
due to the advantage of water-plant relationship 
promoted by mycorrhizal which is the result of 
increases in transpiration rate and stomas opening, 
improved nutritional status and increase of root 
length and depth (MOREIRA; SIQUEIRA, 2006). 

In the field researchthe application of 
formononetin promoted increased mycorrhizal 
colonization from 15 days after germination till  
grain filling (R5.4) and differed significantly (p≤ 
0.05) of the treatment without formononetin (Figure 
1a). This demonstrates the effectiveness of 
formononetin in cropping systems, ensuring the 

stimulating effect of native AMF providing more 
than 20% increase in mycorrhizal colonization, 
regardless of the other factors studied,  several 
studies in greenhouse related the same with this 
plant (BAPTISTA; SIQUEIRA, 1994; PAULA; 
SIQUEIRA, 1990; SILVA-JUNIOR; SIQUEIRA, 
1997). 

The number of nodules varied only due to 
the application of formononetin, with no effect of 
other treatments or the interaction of the factors 
studied. It was observed, as seen in mycorrhizal 
colonization, plants that received formononetin had 
higher number of nodules in relation  the plants that 
not were application of with this product, 
evidencing the favoring of nodulation when  it is 
used (Figure 1b). The isoflavonoid formononetin 
does not induce the activation of nodulation genes 
(HUNGRIA, 1994), but may act indirectly on 
nodulation once it promotes an increase in 
mycorrhizal colonization, increasing the absorption 
of phosphorus, supplying the high demand of this 
nutrient for the nodules. 

 
 
 



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Mycorrhization stimulant…  CORDEIRO, M. A. S. et al. 

Biosci. J., Uberlândia, v. 31, n. 4, p. 1062-1070, July/Aug. 2015 

30

35

40

45

50

55

60

65

70

V3 R2 R5.4

0 Formononetin

0,5  Formononetin

1,0  Formononetin

0

M
y

co
rr

hi
za

l 
co

lo
n

iz
at

io
n

, 
%

Crop Stage  

0

10

20

30

40

0 0,5 1

Formononetin

N
od

u
le

s,
 n
°

p
la

n
ts

-1

 
Figure 1. Mycorrhizal colonization (A) at different stages of soybean and number of nodules (B) at 

flowering, in consolidated no tillage system, depending on the application of formononetin the 
field. Coincident bars do not differ by Tukey test at 5% of probability. 

 
These results corroborate with several 

studies under controlled conditions with soybean 
and isoflavonoid formononetin (FRIES et al., 1998; 
SILVA-JUNIOR; SIQUEIRA, 1997) which 
increases in mycorrhizal colonization stimulated by 
this isoflavonoid were verified. The highest 
mycorrhizal colonization and the  shorter time 
promoted by the use of formononetin represent a 
potential for  soybean crop to overcome adverse 
conditions such as the dry spells and increase the 
efficiency in the use of fertilizers, especially 
phosphorus, commonly occurring factors in the 
Cerrado. 

The soybean production was influenced by 
fungicide and its interaction with formononetin (p ≤ 
0.10) no effect of others treatments and their 
interactions were checked. Fungicide application 

reduced the production of soybeans in 12%, a fact 
confirmed by Zilli et al. (2009). However, when 
there was the use of stimulant to  mycorrhization, 
0.5 mg seed-1 this effect was alleviated, contributing 
to a gain equivalent to 300 kg of soybeans per 
hectare in comparison with  the control without 
formononetin and with fungicides (Table 2), thus 
showing a bioprotection effect promoted by the use 
of formononetin. As the use of these fungicides in 
seed treatment is a very important practice for the 
proper establishment of soybean crop (HENNING et 
al., 2010), the application of formononetin can 
contribute to minimizing the damaging effects of 
fungicides for the mycorrhizal colonization thus 
ensuring the high soybean production in the 
Cerrado.  

 
Table 2. Production of soybeans crop due to the application of fungicide and formononetin, in no tillage 

system of Cerrado. 
Formononetin 
(mg/seed) 

Fungicide 

 Absence Presence 
 kg m-2 

0 0,33 (55) Aa 0,29 (48) Bb 
0,5 0,33 (55) Aa 0,32 (53) Aa 
1,0 0,31 (52) Aa 0,29 (48) Ab 

Means followed by the same capital letter on the line and minuscula letters in the column do not differ by Tukey test at 10 % of 
probability. Values in brackets refer to estimates sacks (60 kg) per hectare. 
 

Another result observed was the not 
inhibition of mycorrhizal colonization due to 
applying fungicide Carbendazim + Thiram even  
Carbendazim belongs to the chemical group of 
benzimidazoles, considered inhibitor of AMF 
(SCHREINER; BETHLENFALVAY, 1997; 
IPSILANTIS et al., 2012; O'CONNOR et al., 
2002;). However, the use of formononetin, dose 0.5, 

served to  increasing the mycorrhizal colonization, 
increasing  the number of nodules (Fig. 1a and b) 
and consequently the protection of the plant to the 
deleterious effects caused by fungicides, (Table 2). 
This is due to changes introduced by formononetin 
in natives AMF that accelerate the mycorrhizal 
colonization and enhance the positive effects of 
these fungi and changes in plant physiology and the 

A) B) 



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Mycorrhization stimulant…  CORDEIRO, M. A. S. et al. 

Biosci. J., Uberlândia, v. 31, n. 4, p. 1062-1070, July/Aug. 2015 

negative effects of pesticides.  Similar effect was 
reported by Siqueira et al. (1991a) for formononetin 
in protecting plants against the residual effect of 
herbicides, confirming the results found in this 
study. 

The foliar nutrients concentrations were not 
affected by experimental treatments and their 
interactions and all the macro and micronutrients 
were found in the proper range for soybean 
(OLIVEIRA, 2004). The concentration of 
phosphorus in all treatments were appropriate, 
however, we can observe a trend (p≤0.20) up to 12 
% increase in levels of this nutrient in plants with 
formononetin (4.72 g kg-1) compared with  the 
control treatment (4.2 g kg-1). This increased the 
absorption of P, even without significant effect, may 
have contributed to the increase in grain production, 
indicating benefits of formononetin even in 
conditions of adequate P supply, as revealed by 
analyzes of the foliar concentrations of this nutrient.  

Thus, with the application of 33% of the 
recommended dose of P, there was no increase in 
foliar levels of this nutrient in the plant, indicating 
that fertilization based on soil chemical analysis, 
was sufficient to ensure adequate phosphate 
nutrition for soybean. Successive fertilization of the 
area assured residual effect of this nutrient in  
consolidated no tillage system (MARTINAZZO et 
al., 2007), situation that may explain the reduced 
effect of formononetin in phosphorus uptake by 
plants observed in this study. 

The application of formononetin promoted a 
52% increase in the production of soybeans crop in 
field experiments  in Lavras (MG) found by 
Siqueira et al. (1992). It is noteworthy that the soil 
conditions, especially the availability of P in the 
soil, the time of adoption of no-tillage system and 
climatic conditions were different from the present 
study. Another aspect that may have contributed to 
the smaller positive effect of formononetin was the 
spore density of native AMF in the soil,  being 
recovered 193 AMF spores 50 mL in soybean 
flowering, considered high for the stimulating action 
of formononetin as reported  by Siqueira et al. 
(1991b). Furthermore, the water regime in the 
period of this study was satisfying and well 

distributed with 1380 mm of rainfall during the crop 
cycle as well as the temperature was favorable to the 
soybean crop (average 24.3 °C) and there was no 
type of environmental stress for culture, unlike what 
occurred in the greenhouse research, where there 
was high water stress and response to application of 
formononetin.  
 The world reserves of phosphate for 
fertilizer production are running out and this is one 
of the major macronutrients responsible for the 
growth of plants (LOPES et al., 2004). Most of the 
phosphorus applied via fertilizer becomes 
unavailable, retained in the soil colloids mainly 
bonded with Fe and Al (PINTO et al., 2013). In this 
sense strategies to increase the efficiency of 
utilization of this phosphorus should be a priority 
for the development of agriculture. The results of 
this study demonstrate the beneficial effects of 
application of formononetin for soybean promoting 
greater mycorrhizal colonization and faster, higher P 
uptake trend, relieving the stress caused by the 
fungicide and water  favoring the increase of 
production of soybean. 

 
CONCLUSIONS 
 

The application of formononetin stimulated 
the mycorrhizal colonization, number of nodules, 
vegetative growth and production of soybean grains 
under conditions of simulated water deficit 

Formononetin applied via seed 0.5 mg seed-1  
caused increased mycorrhizal colonization, nodules 
number and grain production of soybean crop  and 
reduced the negative effects of fungicides 
Carbendazim + Thiram in soybean production in the 
field experiment. 

 
ACKNOWLEDGMENTS 
 

The Federal University of Goiás/Regional 
Jatai – Jataí (GO) by the release of the experimental 
area and logistical support, to CNPq for financial 
support (process 577559/2008-7) and a research 
grant (process 308207/2011-4). To Capes for the 
master’s degree grant given to the first author. 

 
 

RESUMO: Os fungos micorrízicos arbusculares (FMAs) são biotróficos obrigatórios, o que dificulta a 
viabilidade da produção de inoculantes. Com a descoberta de substâncias capazes de estimular a colonização micorrízica, o 
isoflavonóide formononetina surge como uma alternativa promissora para explorar os benefícios dos FMAs nativos do 
solo em cultivos extensivos. O objetivo do presente estudo foi de avaliar os efeitos das aplicações do isoflavonóide 
formononetina (7-hydroxy-4'-methoxy isoflavone) e de fungicida nas sementes em solo do Cerrado no sistema de plantio 
direto com duas doses de fósforo  na cultura da soja em campo e em casa de vegetação. No experimento de campo os 
tratamentos foram três doses de formononetina (0, 0,5 e 1,0 mg de Formononetina semente-1); na ausência e presença de 



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fungicida (Mistura comercial Carbendazim + Thiram) aplicado via semente e duas doses de fósforo (100 % e 33 % da 
adubação recomendada). O experimento de casa de vegetação foi implantado com os mesmos tratamentos utilizado no 
estudo em campo e na fase de florescimento das plantas de soja foi simulado um estresse hídrico, por 10 dias, retornando a 
irrigação normal até a colheita dos grãos. A aplicação de formononetina estimulou aumento da colonização micorrízica, 
número de nódulos, crescimento vegetativo e a produção de grãos soja em condições de déficit hídrico simulado em casa 
de vegetação e no no estudo de campo contribui para amenizar o efeito negativo dos fungicidas nas plantas de soja 
refletindo em aumento da produção da soja.  

 

 
PALAVRAS-CHAVE: Isoflavonóides. Fungo micorrízico. Colonização micorrízica.  Estresse hídrico. Glycine 

max (L) Merril. 
 
 
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