Available via license: CC BY 4.0
Content may be subject to copyright.
Journal of Sustainable Development; Vol. 17, No. 4; 2024
ISSN 1913-9063 E-ISSN 1913-9071
Published by Canadian Center of Science and Education
26
Performance of Corn Hybrids as a Function of Nitrogen Doses and
Trichoderma Harzianum
Bruna Stefhane Santos Reis1, Cíntia da Silva de Oliveira1, Daniel Diego Costa Carvalho1, Francisca Xavier
Quintino Neta1, Cecília Leão Pereira Resende2, Luciana Maria da Silva3 & Fabricio Rodrigues1
1 Universidade Estadual de Goiás, Programa de Produção Vegetal, Unidade Universitária de Ipameri, Goiás, Brazil
2 Universidade Federal de Uberlândia, Programa de Pós-Graduação em Agronomia, Uberlândia, MG, Brasil
3 Instituto Federal Goiano, Programa de Pós-graduação em Ciências Agrárias, Rio Verde, GO, Brazil
Correspondence: Fabricio Rodrigues, Universidade Estadual de Goiás, Rodovia GO 330, Km 241, Anel Viário,
s/no, CEP 75780-000 Ipameri, GO, Brazil. E-mail: fabricio.rodrigues@ueg.br
Received: May 6, 2024 Accepted: June 14, 2024 Online Published: June 19, 2024
doi:10.5539/jsd.v17n4p26 URL: https://doi.org/10.5539/jsd.v17n4p26
Abstract
This study aimed to assess the performance of commercial corn hybrids with the application of Trichoderma
harzianum under varying nitrogen levels. The experiment was conducted at the State University of Goiás, Campus
Sul, during the 2022/23 harvest. The experimental design employed a factorial scheme 9 x 3, involving nine
commercial hybrids and three nitrogen doses, randomized in blocks with three replications. Three nitrogen doses
were applied: control (160 kg ha-1 of nitrogen), low nitrogen (80 kg ha-1 of nitrogen), and low nitrogen (80 kg ha-
1 + Trichoderma harzianum). The evaluation encompassed ear height, plant height, relative chlorophyll index,
stem diameter, number of rows, number of lines, and dry grain mass. The hybrids 2M77, 2M80, P3898, and P4285
exhibited superior efficiency with 80 kg ha-1 of nitrogen, while DKB390 and P3898 demonstrated the highest
responsiveness to the recommended dose of 160 kg ha-1 of nitrogen. The inoculation of Trichoderma harzianum,
combined with 80 kg ha-1 of nitrogen, resulted in increased grain mass, in the hybrids 30A91PW, DKB390,
GNZ7280, P4285, and RK3014, with variable benefits across different characteristics. However, it is advisable to
limit the use of Trichoderma harzianum to these specific commercial cultivars.
Keywords: Zea mays, bioinput, biostimulant, synergism, urea
1. Introduction
In achieving high yields in maize cultivation, nitrogen (N) stands as one of the pivotal fertilizers, yet it is frequently
mismanaged by producers (Ransom et al., 2020). Studies indicate that approximately 30 to 40% of applied N is
absorbed by plants, while over 60% remains in the soil, commonly lost through leaching, surface runoff,
denitrification, volatilization, and microbial consumption (Santos et al., 2019).
Continuous investments in the genetic enhancement of corn aiming to bolster productivity, agronomic adaptability,
and resilience to climatic variations persist as concerns within the agricultural sector and for food security (Gedil
& Menkir, 2019). Thus, a potential avenue could involve blending organic technologies with the utilization of
microorganisms that facilitate plant development. This synergistic effect within the root zone could foster
sustainability in modern agriculture, enabling producers to achieve heightened yields without added burdens
(Baez-Rogelio et al., 2017).
The Trichoderma fungus has been extensively used in agricultural practices as a more efficient cost-effective
approach, presenting itself as an enhancer in the use of endogenous nitrogen, due to its symbiotic association, its
capacity encompasses the regulation of the transcription of nitrate, phytohormones (auxin, gibberellins, cytokinin
and ethylene) and positively regulated in the absorption of this nutrient (Singh et al., 2019).
As per Sood et al. (2020), Trichoderma spp. exerts a beneficial influence on diverse physiological systems in plants,
including processes like photosynthesis, stomatal conductance, gas exchange, nutrient absorption, water use
efficiency, and more. Consequently, these microorganisms can enhance root growth and augment the uptake of
mineral nutrients and water from the soil. In corn, Airspe-Vásquez et al. (2023) tested promotion with T. asperellum,
T. harzianum and T. longibrachiatum, in different corn genotypes, which resulted in an increase in productivity in
specific genotypes, a reduction in diseases and enabling producers to grow crops with greater profitability,
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
27
especially when using T. asperellum - T11.
This study aimed to assess the performance of commercial corn hybrids with the application of Trichoderma
harzianum under varying nitrogen levels.
2. Method
The experiment took place at the State University of Goiás, South Campus, Ipameri University Unit (Lat. 17° 42'
59.12" S, Long. 48°08' 40.49" W, Alt. 773 m), specifically in the unit's experimental farm, during the 2022/23
growing season. The soil used for cultivation was a Dystrophic Red Latosol (Oxisols) (Santos et al., 2018). The
region's climate falls under the Tropical (Aw) classification by Köppen, characterized by dry winters, humid
summers, and an average temperature of 20°C (Alvares et al., 2013).
The experiment followed a randomized block design with a factorial scheme (9 x 3) and three replications. The
study involved nine distinct commercial hybrids (as detailed in Table 1) subjected to three N doses at the base:
control (160 kg ha-1 of N), low N (80 kg ha-1 of N), and low N+ (80 kg ha-1 of N with the application of Trichoderma
harzianum - Ecotrich® WP - isolate IBLF 006), and for all treatments 140 kg ha-1 of P2O5, and 90 kg ha-1 of K2O,
according Faria et al. (2023b). Experimental plots consisted of two 4m rows, with a row spacing of 0.45m and
three plants per meter, resulting in an approximate stand of 66,000 plants.
The soil was conventionally prepared with one plowing and two harrowing’s, followed by the use of a cultivator
to open the sowing furrows. The soil has a medium texture and was fertilized based on the soil analysis results
(Table 2). The fertilizer sources used were urea (45% N), simple superphosphate (18% P2O5) and potassium
chloride (60% K2O), with application in the sowing furrow and with coverage only in the control with equitable
distribution between doses.
Table 1. Agronomic characteristics of the commercial corn hybrids used in the experiment
Commercial
Hybrids Availability
Hybrid
Typ e
Main
Use
Plant
Height
(cm)
Degree
Days Cycle
Grain
Color
Grain
Typ e
2M77 MC/SC S GR 240 850 PRE AL SD
2M80 MC/SC S GR 215 - PRE AL/AV SD
30A91PW MC/SC SM GR/SL 230 902 PRE AM/AL SD
ADV9860 MC/SC S GR 230-250 880 PRE AL SD
DKB390 SC S GR 251 870 PRE AM/AL SD
GNZ7280 MC/SC S GR 230-270 840 PRE AL SD
P3898 MC/SC - GR/SL 257 - PRE SI SD
P4285 MC/SC S GR/SL 295 142 PRE AM D
RK3014 MC/SC T GR/SL 225-240 830 PRE AL D
MC- Main Crop; SFR- Second Crop; S- Simple; SM- Modified Simple; T- Triple; GR- Grains; SL- Silage; PRE-
Early; AL- Orange-colored; AV- Reddish; AM- Yellowish; SD- Semi-hard; D- Hard.
The seeds were treated with Trichoderma harzianum – isolate IBLF 006 (Ecotrich WP; Ballagro Agro Tecnologia
Ltda., Piracicaba, SP, Brazil), which was placed in direct contact with the T. harzianum isolate in an amount of 8
mL of suspension, at a dose of 2.5x108 cells/100 g of seed, the dose being based on results obtained by Oliveira et
al. (2018) in wheat, using a manual pressure sprayer (550 mL) until they were soaked and immediately in the field,
manually.
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
28
Table 2. Main chemical characteristics of the soil (0-20 cm depth) without any application of fertilizer or lime.
Ipameri, GO, UEG
Traits
pH M.O. Presina H+Al K Ca Mg SB CTC V%
CaCl2 g dm-3 mg dm-3 ______________________mmol dm-3_______________________
Solo 4.9 24.1 9.0 30.3 4.1 18.2 7.5 27.8 57.6 47.7
pH - active acidity, M.O. - Organic matter, P - Available Phosphorus, H+Al - Potential acidity, k - Available
Potassium, Ca - Exchangeable Calcium, Mg - Exchangeable Magnesium, CTC - Effective Cation Exchange
Capacity, V% - Base saturation.
Cultivation consisted of manual weeding to control weeds and the application of phytosanitary products, including
chlorantraniliprole 100 gr L-1 + lambda-cyhalothrin 50 gr L-1 (Ampligo®) at a rate of 150 mL ha-1 to control
cartridge caterpillars (Spodoptera frugiperda) according Cintra et al. (2023).
The assessment covered several characteristics: Ear Height (EH) - measured as the distance in centimeters from
the ground to the main ear; Plant Height (PH) - measured as the height in centimeters from the ground to the plant's
top (stem apex); Relative Chlorophyll Index (RCI) - measured with the CFL1030 (SN0359) instrument, expressed
in grams of chlorophyll, taken from three fully expanded leaves in the middle section of the plants, 80 days after
sowing; Stem Diameter (SD) - determined as the average diameter in millimeters of five representative plants in
the plot, at the base of the plant; Number of Lines in the Ear (NLE) - the number of rows in three representative
ears in the plot; Number of Rows (NR) - the number of rows in three representative ears in the plot; Grain Mass
(GM) - calculated as the weight of the harvested plot (usable area) and converted to kilograms per hectare,
according Faria et al. (2023a).
The collected data underwent variance analysis followed by the Scott-Knott test at a 5% probability using the
Sisvar software (Ferreira, 2011).
3. Results and Discussion
Significant differences (p≤0.01) were observed for the factors of dose, hybrid, and their interaction (dose x hybrid)
across all analyzed variables, except for stem diameter, indicating varied impacts of Trichoderma harzianum
inoculation alongside nitrogen doses on both primary and secondary components in maize plants (Table 3).
Table 3. Summary of the mean square of the variables ear height (EH), plant height (PH), relative chlorophyll
index (RCI), stem diameter (SD), number of rows (NR), number of lines (NL), and grain mass (GM) in nine corn
hybrids under different nitrogen fertilization conditions
F.V. df EH PH RCI SD NR NL GM
Dose (D) 2 464.3** 2287.7** 139.4** 0.2N.S. 21.5** 227.4** 5865640.2**
Hybrid (H) 8 21.3** 137.7** 31.0** 3.5** 1.4** 25.7** 139”3282.1**
D x H 16 29.6** 76.4** 11.8** 1.8** 1.7** 6.4** 2105193.3**
Block 2 3.0 9.6 6.6 0.0 0.0 2.9 51007.3
Error 52 4.7 16.2 2.5 0.3 0.3 2.2 313775.8
Cv (%) 3.4 2.2 4.3 3.3 3.4 4.0 9.1
N.S. not significant; ** - highly significant; * - significant; 5% probability, by F test; CV (%) - coefficient of variation.
Regarding ear height and plant height variables, hybrids 2M80, 30A91PW, and DKB390 exhibited superior
performance under the low N+ treatment (80 kg + Trichoderma harzianum), comparable to outcomes in the low N
treatment (80 kg) and similar to the control (160 kg), refer to Table 4. For the variable ear height, the differences
presented were 9.8, 16.1 and 17.2%, while for plant height they were 9.4, 8.2 and 17.5%, respectively, and it was
observed than the hybrid GNZ7280, with an increase of approximately 13%, in relation to low N, with an average
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
29
gain of 6.8% for ear height and 6.2% for the plant, depending on availability, which indicates the potential of the
T. harzianum to promote growth in some corn hybrids.
According to Contreras-Cornejo et al. (2009), the promotion of plant growth is facilitated by the utilization of
Trichoderma spp., which is linked to the production of phytohormones like auxin through indoleacetic acid (IAA)
and indole acetaldehyde synthesized by T. vire ns and T. atroviride. These compounds are responsible for
stimulating plant root growth, leading to increased biomass and the development of lateral roots in Arabidopsis
seedlings. Enhanced root development results in improved soil exploration efficiency, facilitating greater uptake
of water and nutrients, and consequently enhancing plant growth (both height and stem diameter).
Divergent outcomes were reported by Yang et al. (2022), who studied corn with the inoculation of arbuscular
mycorrhizal fungi (AM), T. longibrachiatum (MF), Glomus sp. (Gm), T. longibrachiatum + Glomus sp. (Gm +
MF), and compared them against the non-inoculated control, under two salinity levels (0 and 75 mM NaCl). Their
application individually did not yield growth increases; however, combinations like AM + MF increased plant
biomass by 58.3%, and Gm + MF by 68.6%, compared to the non-inoculated at 0 salinity levels. The authors
concluded that dual inoculation proves more efficient for plant growth in non-saline conditions than single
applications.
The promotion of both plant height and stem diameter in corn was observed by Araújo et al. (2023), with the use
of T. harzianum, in five treatments and the largest quantity (800 ml), twice that recommended by the company, in
this case, it was the one that presented the greatest promotion, with linear performance and greater benefits in other
variables. It is important to report the greater growth of the root (dry mass and length) as well, which would be
directly related to the absorption of water and nutrients.
The findings from this research were validated by Muter et al. (2017), who demonstrated that the introduction of
Trichoderma viride and charcoal in maize led to a 5.6% increase in plant height (T. v i r ide treatment) and 14.34%
(T. vir i d e + charcoal), compared to the control (without application), at 55 days after implantation. This
combination promoted growth, and laser microscopy revealed a continuous, dense biofilm in soil particles sampled
from the rhizosphere, responsible for immobilizing T. v i r i d e in the soil.
Hybrids 30A91PW, DKB390, GNZ7280, P3898, and P4285 exhibited superior performance in the relative
chlorophyll index under low N+ treatment, with increases of 18.4, 8.67, 14.2, 15.2, and 5.4%, respectively,
compared to low N treatment, showing similar performance to the control. This indicated enhanced photosynthetic
rates and potentially improved utilization of photoassimilates, averaging 6.6% (Table 4). Higher chlorophyll
content in plants may result from increased nitrogen availability, aligning with Li et al. (2019) findings that higher
nitrogen availability correlates with increased chlorophyll content and rates.
Estévez-Geffriaud et al. (2020) assessed the impact of inoculating Trichoderma asperellum (strain T34), with or
without a chemical fungicide (Q), on maize growth and various variables under both irrigated systems and water
deficiency conditions. The application proved beneficial in irrigated systems, enhancing the number and weight
of grains and emphasizing hydration and photosynthetic capacity.
Yadav et al. (2018) found that the inoculation of Trichoderma viride, combined with fertilizer doses, positively
affected the chlorophyll content of leaves and root length of the G-5414 variety. The analyses were carried out at
20, 40 and, with emphasis on 60 days, for treating T. v i r i de + 75% of the recommended doses of NPK (120-60-60
kg ha-1), which resulted in a chlorophyll content 42% higher than the control, therefore, the use of the fungus and
a reduced dose of fertilizers were efficient in promoting plant growth and productivity.
Inoculation with T. harzianum isolate IBLF 006WP resulted in a 0.7% improvement in stem diameter compared
to low N and a 1.3% improvement compared to the control. Commercial hybrids 30A91PW and ADV9860 in the
low N+ treatment showed 12.1 and 6.4% improvements, respectively, over low N, similar to the control (Table 4),
suggesting the fungus application's potential to increase stiffness and possibly reduce losses during mechanized
harvesting due to lodging.
Nepali et al. (2020) inoculated maize with 2.5 ml of a commercial product containing Trichoderma viride in 1 kg
of seed, combined with 50% (120:60:40 kg NPK ha-1) of the recommended fertilizers, resulting in a 1 cm increase
in stem diameter compared to the control. Their study concluded that using T. v iride + 50% of the recommended
fertilizers effectively promoted growth and crop yield, demonstrating its potential as a biofertilizer and growth
promoter.
It was found that for the variable number of rows, the 2M77 and ADV9860 hybrids were the only ones that did
not show promotion when comparing low N and low N with T. harzianum, whereas the 30A91PW and P4285
hybrids obtained superior performance above the control (Table 5). The general averages refer to this increase,
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
30
with an increase of 9.3% with the combination, but the condition is not repeated in the number of lines and, on
average, the reduction was 4.4%. Steffen et al. (2021) did not find a significant difference for the number of rows
in corn but detected a difference for the number of lines and an increase in yield of 17.6% in the crop.
Table 4. Ear height (EH), plant height (PH), relative chlorophyll index (RCI) and stem diameter (SD) in nine corn
hybrids as a function of nitrogen doses, with Trichoderma harzianum application
Hybrids ----------- EH ---------- ---------- PH ----------
- 80 kg ha-1 - - 80 kg ha-1+ - - 160 kg ha-1 - - 80 kg ha-1 - - 80 kg ha-1+ - - 160 kg ha-1 -
2M77 63.1 aA 65.7 aA 67.8 bA 174.9 aC 182.6 bB 194.9 aA
2M80 61.2 aB 65.9 aA 68.5 bA 176.2 aB 191.2 aA 194.5 aA
30A91PW 57.6 bB 66.6 aA 67.2 bA 172.4 aB 187.9 aA 185.4 bA
ADV9860 58.1 bB 63.3 bA 63.9 cA 173.6 aB 172.6 cB 185.2 bA
DKB390 56.6 bB 68.1 aA 64.6 cA 159.4 bB 184.4 aA 190.1 bA
GNZ7280 58.2 bC 67.7 aB 73.9 aA 171.4 aB 194.0 aA 189.6 bA
P3898 61.9 aB 60.3 bB 73.4 aA 175.5 aB 179.6 bB 195.4 aA
P4285 64.7 aB 62.8 bB 68.6 bA 179.7 aC 188.3 aB 195.6 aA
RK3014 60.0 bB 61.3 bB 68.0 bA 171.8 aB 177.6 bB 188.0 bA
Means 60.2 64.6 68.4 172.8 184.2 191.0
Hybrids ---------- RCI ---------- ---------- SD ----------
- 80 kg ha-1 - - 80 kg ha-1+ - - 160 kg ha-1 - - 80 kg ha-1 - - 80 kg ha-1+ - - 160 kg ha-1 -
2M77 37.0 aA 35.7 bA 37.8 bA 15.2 bA 14.3 bB 15.3 bA
2M80 33.7 bB 34.5 cB 39.1 bA 15.4 bA 14.2 bB 15.3 bA
30A91PW 31.5 bB 37.3 bA 38.1 bA 15.1 bB 16.2 aA 13.8 cC
ADV9860 34.2 bB 33.7 cB 38.0 bA 14.2 cB 14.9 bA 13.8 cC
DKB390 32.3 aC 35.1 cB 39.5 bA 14.5 cA 15.3 bA 15.1 bA
GNZ7280 36.0 aB 41.1 aA 38.9 bA 15.0 bB 17.0 aA 16.5 aA
P3898 36.3 aB 41.8 aA 42.2 aA 16.4 aA 14.7 bB 16.2 aA
P4285 35.5 aB 41.4 aA 40.9 aA 14.7 cA 15.0 bA 14.3 cA
RK3014 33.2 bB 35.0 bB 38.9 bA 14.4 cA 14.3 bA 14.1 cA
Means 34.7 37.0 39.3 15.0 15.1 14.9
80 kg ha-1 - Low N, 80 kg ha-1+ - Low N with Trichoderma harzianum application and 160 kg ha-1 – Control; means
followed by the same lowercase letter in the vertical and uppercase horizontally do not differ from each other by
the Scott-Knott test at 5% probability.
Fu et al. (2019) inoculated Trichoderma asperellum, diluted in 200 ml of water, under treatments W4 - 0.7 and W6
- 1.4 g of conidia, using root irrigation. They observed that for two consecutive years, the crop was responsive,
showing an increase in productivity of approximately 4.87 and 10.95% in 2015, and 5.75 and 12.41% in 2016.
This led to the conclusion that the continuous use of T. asperellum improved crop yields over time and increased
the overall abundance of bacteria in the soil, benefitting the rhizosphere. Soil microbes, in response, modify plant
performance as the microflora diversity increases, leading to more frequent interactions and subsequently
enhanced nutrient availability for plants.
In relation to grain mass, in the low availability condition, the performance of the one with T. harzianum surpassed
that without application by 16.2%, in the general average, and also by 5.7% compared to the control (Table 5). The
hybrids 30A91PW, GNZ7280 and P4285 outperformed even the control, indicating the high synergism and good
combination between the genotype and the environment generated by the fungus (rhizosphere). The hybrids
DKB390 and RK3014, in low N and T. harzianum, obtained the same yield seen in the control, with promotion
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
31
and capacity for drastic reduction of fertilization (80 kg ha-1).
Table 5. Number of rows (NR), number of lines (NLE), and grain mass (GM) in nine corn hybrids as a function of
nitrogen dose, with Trichoderma harzianum application
Hybrids ------------ NR ------------ ------------ NLE ------------
- 80 kg ha-1 - - 80 kg ha-1+ - - 160 kg ha-1 - - 80 kg ha-1 - - 80 kg ha-1+ - - 160 kg ha-1 -
2M77 16.7 aB 17.5 aB 18,6 aA 37,0 bB 34,8 bB 41,0 bA
2M80 16.8 aB 18.0 aA 18,0 aA 37,6 bB 35,2 bB 41,6 bA
30A91PW 15.6 bC 18.6 aA 17,4 bB 35,3 bB 39,2 aA 39,3 bA
ADV9860 16.4 aA 16.1 bA 17,0 bA 35,2 bB 31,5 cC 39,2 bA
DKB390 15.0 bC 16.7 bB 18,4 aA 34,0 bB 32,4 cB 38,0 bA
GNZ7280 15.8 bB 18.4 aA 18,3 aA 35,6 bB 35,9 bB 39,6 bA
P3898 15.9 bB 17.7 aA 18,2 aA 36,7 bB 33,3 cC 40,7 bA
P4285 17.2 aB 18.3 aA 16,8 bB 40,6 aA 36,0 bB 44,6 aA
RK3014 16.3 aB 17.6 aA 17,3 bA 35,2 bB 34,1 cB 39,2 bA
Means 16.2 17.7 17,8 36,3 34,7 40,3
Hybrids ------------------------ GM ------------------------
- 80 kg ha-1 - - 80 kg ha-1+ - - 160 kg ha-1 -
2M77 6303.1 aA 6631.4 cA 6463,9 bA
2M80 6551.8 aA 7266.0 bA 5822,3 bB
30A91PW 5359.2 bB 8768.3 aA 5812,0 bB
ADV9860 5439.9 bB 4876.2 dB 6233,0 bA
DKB390 4985.7 bB 5946.3 cA 6862,7 aA
GNZ7280 5431.2 bB 7283.5 bA 6237,5 bB
P3898 6094.4 aB 5751.9 cB 7192,5 aA
P4285 6193.6 aB 7048.2 bA 5770,9 bB
RK3014 5006.2 bB 6111.0 cA 6078,3 bA
Means 5707.2 6631.4 6274.8
80 kg ha-1 - Low N, 80 kg ha-1+ - Low N with Trichoderma harzianum application and 160 kg ha-1 – Control; means
followed by the same lowercase letter in the vertical and uppercase horizontally do not differ from each other by
the Scott-Knott test at 5% probability.
Akladious & Abbas (2013) noted the impact of Trichoderma harzianum on maize, observing substantial growth
promotion and vigor. Their findings showed significant outcomes in plant height, leaf area, and fresh weight of the
aerial part, among other variables related to root development. Similarly, Nepali et al. (2020) evaluated
Trichoderma viride's capacity as a biofertilizer, suggesting its potential to enhance growth and productivity,
potentially reducing the requirement for mineral fertilizers. Their study highlighted significant differences in
variables such as plant height, stem diameter, and leaf area index, consistent with the findings in this research.
Qiao et al. (2019) reported that in a field experiment comparing chemical (CF), organic (OF), and bio-organic
fertilizer regimes, along with Trichoderma guizhouense (strain NJAU 4742 - BOF), there was a corn yield increase
by 216 kg acre-1 (533.75 kg ha-1) compared to chemical fertilizers, which was comparable to organic fertilizers.
The study concluded that fertilizer choice directly impacted soil microbiota and demonstrated the fungus's greater
efficacy in enhancing crop yields due to improved microbiota and soil quality.
Lu et al. (2020) aimed to mitigate the impact of stem rot disease on maize by inoculating Trichoderma asperellum
GDFS1009 granules (2, 4, 5, 6, 8, and 10 g/hole) with 45 kg/667m2 of chemical fertilizers. The application of 10
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
32
g of T. asperellum in conjunction with fertilizers reduced disease impact by 72.05% and increased crop yield by
11.28% compared to the control (without T. asperellum). This control led to disease containment and served as a
positive promoter for crop growth.
The hybrids 30A91PW, DKB390, GNZ7280 and P4285 presented higher values of plant height, relative
chlorophyll index, stem diameter and number of rows, which indirectly contributed to improving plant yield, ear
formation and possibly grains weight, when the isolate IBLF 006 was applied. The RK3014 hybrid only obtained
promotion for the variable number of rows, without changes in other variables when the same analysis is carried
out, which denotes that new characteristics must be studied in order to detect which are most important in
increasing productivity.
4. Conclusion
The application of Trichoderma harzianum makes it possible to reduce the nitrogen dose by 80 kg ha-1, promoting
the improvement and maintenance of plant productivity and, in some corn hybrids, with benefits that surpass even
the recommended fertilization.
The hybrids 30A91PW, DKB390, GNZ7280, P4285 and RK3014 showed greater synergism and improvement in
the rhizosphere when Trichoderma harzianum (isolate IBLF 006) was applied, in combination with a dose of 80
kg ha-1, with increment in five variables, however, the application is only indicated for these hybrids.
References
Akladious, S. A., & Abbas, S. M. (2013). Application of Trichoderma harzianum T22 as a biofertilizer potential
in maize growth. Journal of Plant Nutrition, 37(1), 30-49. https://doi.org/10.1080/01904167.2013.829100
Alvares, C. A., Stape, J. L., Sentelhas, P. C., Gonçalves, J. D. M., & Sparovek, G. (2013). Mapa de classificação
climática de Köppen para do Brasil. Meteorologische Zeitschrift, 22, 711-728.
Araújo, T. B., Schuelter, A. R., Souza, I. R. P., Coelho, S. R. M., & Christ, D. (2023). Growth promotion in maize
inoculated with Trichoderma harzianum. Revista Brasileira de Milho e Sorgo, 22(e1269), 1-19.
https://doi.org/10.18512/rbms2023v22e1269
Arispe-Vázquez, J. L., Sánchez-Arizpe, A, Cadena-Zamudio, D. A., Galindo-Cepeda, M. E., Noriega-Cantú, D.
H., Barrón-Bravo, O. G., Carnero-Avilés, L., Mayo-Hernández, J., Ramírez-Sánchez, S. E., & Antonio-
Bautista, A. (2009). The beneficial effect of Trichoderma spp. in seed treatment of four maize (Zea mays L.)
genotypes. American Journal of Plant Sciences, 4(6), 625-637. https://doi.org/ 10.4236/ajps.2023.146042
Baez‐Rogelio, A., Morales‐García, Y. E., Quintero‐Hernández, V., & Muñoz‐Rojas, J. (2017). Next
generation of microbial inoculants for agriculture and bioremediation. Microbial biotechnology, 10(1), 19-
21. https://doi.org/10.1111/1751-7915.12448
Cintra, P. H., Resende, C. L., Damaso, L. F., Carvalho, D. D. C., Silva, F. D. C., & Rodrigues, F. (2023). Five
cycles of intrapopulation recurrent selection in half-sib progenies of fresh corn. Revista Caatinga, 36(3), 723-
730. http://dx.doi.org/10.1590/1983-21252023v36n324rc
Contreras-Cornejo, H. A., Macías-Rodríguez, L., Cortés-Penagos, C., & López-Bucio, J. (2009). Trichoderma
virens, a plant beneficial fungus, enhances biomass production and promotes lateral root growth through an
auxin-dependent mechanism in Arabidopsis. Plant physiology, 149(3), 1579-1592.
https://doi.org/10.1104/pp.108.130369
Estévez-Geffriaud, V., Vicente, R., Vergara-Díaz, O., Narváez Reinaldo, J. J., & Trillas, M. I. (2020). Application
of Trichoderma asperellum T34 on maize (Zea mays) seeds protects against drought stress. Planta, 252(8),
1-12. https://doi.org/10.1007/s00425-020-03404-3
Faria, M. M., Cintra, P. H. N., Amorin, V. A., Campos, T. S., Rocha, E. C., & Rodrigues, F. (2023). Interrelation
between potassium rates and the efficiency of Bt genes in the control of Spodoptera frugiperda. Pesquisa
Agropecuária Brasileira, 58(e03241), 1-9. https://doi.org/10.1590/S1678-3921.pab2023.v58.03241
Faria, M. M., Ribeiro, W. N., Almeida, Q. R., Reis, B. S. S., Resende, C. L. P., & Rodrigues, F. (2023). Interrelation
between nitrogen doses and the efficiency of Bt genes in the control of Spodoptera frugiperda. Journal of
Sustainable Development, 16(6). https://doi.org/10.5539/jsd.v16n6p71
Ferreira, D. F. (2011). Sisvar: A computer statistical analysis system. Ciência e Agrotecnologia, 35(6), 1039-1042.
https://doi.org/10.1590/S1413-70542011000600001
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
33
Fu, J., Xiao, Y., Wang, Y. F., Liu, Z. H., & Yang, K. J. (2019). Trichoderma affects the physiochemical
characteristics and bacterial community composition of saline–alkaline maize rhizosphere soils in the cold-
region of Heilongjiang Province. Plant and Soil, 436, 211-227. https://doi.org/10.1007/s11104-018-03916-8
Gedil, M., & Menkir, A. (2019). An integrated molecular and conventional breeding scheme for enhancing genetic
gain in maize in Africa. Frontiers in Plant Science, 10(1430), 1-17. https://doi.org/10.3389/fpls.2019.01430
Li, N., Yang, Y., Wang, L., Zhou, C., Jing, J., Sun, X., & Tian, X. (2019). Combined effects of nitrogen and sulfur
fertilization on maize growth, physiological traits, N and S uptake, and their diagnosis. Field Crops Research,
242(107593), 1-10. https://doi.org/10.1016/j.fcr.2019.107593
Lu, Z. X., Tu, G. P., Zhang, T., Li, Y. Q., Wang, X. H., Zhang, Q. G., Song, W., & Chen, J. (2020). Screening of
antagonistic Trichoderma strains and their application for controlling stalk rot in maize. Journal of Integrative
Agriculture, 19(1), 145-152. https://doi.org/10.1016/S2095-3119(19)62734-6
Muter, O., Grantina-Ievina, L., Makarenkova, G., Vecstaudza, D., Strikauska, S., Selga, T., Kasparinskis, R.,
Stelmahere, S., & Steiner, C. (2017). Effect of biochar and Trichoderma application on fungal diversity and
growth of Zea mays in a sandy loam soil. Environmental & Experimental Biology, 15, 289-296.
https://doi.org/10.22364/eeb.15.30
Nepali, B., Subedi, S., Bhattarai, S., Marahatta, S., Bhandari, D., & Shrestha, J. (2020). Bio-fertilizer activity of
Trichoderma viride and Pseudomonas fluorescens as growth and yield promoter for maize. Journal of
Agricultural Science, 31(2), 191-195. https://doi.org/10.15159/jas.20.17
Oliveira, J. B., Muniz, P. H. P. C., Peixoto, G. H. S., De Oliveira, T. A. S., Duarte, E. A. A., Rodrigues, F., &
Carvalho, D. D. C. (2018). Promotion of seedling growth and production of wheat by using Trichoderma spp.
Journal of Agricultural Science, 10(8), p. 267-276, 2018. https://doi.org/10.5539/jas.v10n8p267
Qiao, C., Penton, C. R., Xiong, W., Liu, C., Wang, R., Liu, Z., Xu, X., Li, R. & Shen, Q. (2019). Reshaping the
rhizosphere microbiome by bio-organic amendment to enhance crop yield in a maize-cabbage rotation system.
Applied Soil Ecology, 142, 136-146. https://doi.org/10.1016/j.apsoil.2019.04.014
Ransom, C. J., Kitchen, N. R., Camberato, J. J., Carter, P. R., Ferguson, R. B., Fernández, F. G., Franzen, D. W.,
Laboski, C. A. M., Nafziger, E. D., Sawyer, J. E., Scharf, P. C., & Shanahan, J. F. (2020). Corn nitrogen rate
recommendation tools’ performance across eight US midwest corn belt states. Agronomy Journal, 112, 470-
492, 2020. https://doi.org/10.1002/agj2.20035
Resende, C. L. P., Martins, J. B., Ilaria, F. R., Santos, C. M. M., & Rodrigues, F. (2021). Phenotypic and genetic
parameters estimated for fresh corn under different nutrient availability. Revista Caatinga, 34(4), 752-762.
https://doi.org/10.1590/1983-21252021v34n402rc
Santos, A. D., Amaral Júnior, A. T. D., Fritsche-Neto, R., Kamphorst, S. H., Ferreira, F. R. A., Amaral, J. F. T.
D., Vivas, J. M. S., Santos, P. H. A. D., Lima, V. J. de., Khan, S., Schmitt, K M. F., Leite, J. T., Junior, D. R.
dos S., Bispo, R. B., Santos, T. de O., Oliveira, U. A. de., Guimarães, J. J. M., & Rodriguez, O. (2019).
Relative importance of gene effects for nitrogen-use efficiency in popcorn. Plos one, 14(e0222726), 1-13.
https://doi.org/10.1371/journal.pone.0222726
Santos, H. G. dos, Jacomine, P. K. T., Anjos, L. H. C. dos, Oliveira, V. A. de, Lumbreras, J. F., Coelho, M. R.,
Almeida, J. A. de, Araujo Filho, J. C. de, Oliveira, J. B. de, & Cunha, T. J. F. (2018). Sistema Brasileiro de
Classificação de Solos (5th ed.). Brasília: Embrapa.
Singh, B. N., Dwivedi, P., Sarma, B. K., Singh, G. S., & Singh, H. B. (2019). A novel function of N-signaling in
plants with special reference to Trichoderma interaction influencing plant growth, nitrogen use efficiency,
and cross talk with plant hormones. Biotech, 9(109), 1-13. https://doi.org/10.1007/s13205-019-1638-3
Sood, M., Kapoor, D., Kumar, V., Sheteiwy, M. S., Ramakrishnan, M., Landi, M., Araniti, F., & Sharma, A. (2020).
Trichoderma: The “secrets” of a multitalented biocontrol agent. Plants, 9(762), 1-25.
https://doi.org/10.3390/plants9060762
Steffen, G. P. K., Tomazzi, D. J., Steffen, R. B., Gabe, N. L., Silva, R. F. da, Mortari, J. L. M., Maldaner, J., &
Santos, G. F. P. (2021). Incremento da produtividade de milho pela inoculação de Trichoderma Harzianum.
Brazilian Journal of Development, 7(1), 4455-4468. https://doi.org/10.34117/bjdv7n1-301
Yadav, R. S., Singh, V., Pal, S., Meena, S. K., Meena, V. S., Sarma, B. K., Singhc, H. B., & Rakshit, A. (2018).
Seed bio-priming of baby corn emerged as a viable strategy for reducing mineral fertilizer use and increasing
productivity. Scientia horticulturae, 241(18), 93-99. https://doi.org/10.1016/j.scienta.2018.06.096
jsd.ccsenet.org Journal of Sustainable Development Vol. 17, No. 4; 2024
34
Yang, R., Qin, Z., Wang, J., Zhang, X., Xu, S., Zhao, W., & Huang, Z. (2022). The interactions between arbuscular
mycorrhizal fungi and Trichoderma longibrachiatum enhance maize growth and modulate root metabolome
under increasing soil salinity. Microorganisms, 10(5), 1-17.
https://doi.org/10.3390/microorganisms10051042
Acknowledgments
The authors thank the Universidade Estadual de Goiás for the financial support provided through Call Notice No.
21/2022 - Pro-Programs.
Authors contributions
Not applicable.
Funding
Not applicable.
Competing interests
Not applicable.
Informed consent
Obtained.
Ethics approval
The Publication Ethics Committee of the Canadian Center of Science and Education.
The journal’s policies adhere to the Core Practices established by the Committee on Publication Ethics (COPE).
Provenance and peer review
Not commissioned; externally double-blind peer reviewed.
Data availability statement
The data that support the findings of this study are available on request from the corresponding author. The data
are not publicly available due to privacy or ethical restrictions.
Data sharing statement
No additional data are available.
Open access
This is an open-access article distributed under the terms and conditions of the Creative Commons Attribution
license (http://creativecommons.org/licenses/by/4.0/).
Copyrights
Copyright for this article is retained by the author(s), with first publication rights granted to the journal.