ABSTRACT

Seed microbiolization has been increasingly contributed to researches due to its beneficial action in the initial growth of seedlings and control of phytopathogens. Thus, the aim of this study was to evaluate the initial growth and control of fungi associated with cowpea seeds by the seed microbiolization with commercial strains of Trichoderma spp. Seeds of cowpea cultivar 'BRS Gurguéia' were analyzed in a completely randomized design, with four replications, using five commercial strains based on Trichoderma asperellum and T. harzianum (Trichodermax®, Quality®, Trichodermil®, Agroguard® and Ecotrich®) and two control treatments, represented by untreated seeds (negative control) and the fungicide carbendazim (positive control). Sanity, germination, emergence and electrical conductivity tests of seeds were carried out to confirm the hypotheses. Seed microbiolization with Trichoderma asperellum and Trichoderma harzianum are effective in reducing the incidence of fungi and have antimicrobial activity similar to synthetic fungicide. The strains T. asperellum T-211 (Trichodemax®), T. asperellum URM-5911 (Quality®) e T. harzianum ESALQ-1306 (Trichodermil®) promote increases for seed vigor. The percentage of seed emergence is maximized with the application of strains T. asperellum (Quality® and Trichodemax®). The commercial strains of Trichoderma tested increase the initial growth of cowpea seedlings cv. 'BRS Gurguéia'.

Keywords
biological control; Vigna unguiculata ; biological products; plant pathogens

INTRODUCTION

Cowpea (Vigna unguiculata (L.) Walp.) is one of the most cultivated and consumed grain legumes in Brazil, with emphasis on the North and Northeast regions, where it is an important source of income and subsistence for small producers who live on family farming (Lima et al., 2014Lima JME, Fagundes GS, & Smiderle OJ (2014) Qualidade fisiológica de sementes de feijão-caupi tratadas com terra diatomácea e infestadas por carunchos. Revista em Agronegócios e Meio Ambiente, 7:733-746.).

According to data from the Brazilian National Supply Company (Conab), cowpea production was estimated at 637.7 thousand metric tons of grains in 2018/2019 (Conab, 2019CONAB - Companhia Nacional de Abastecimento (2019) Acompanhamento da safra brasileira de grãos: safra 2018/2019. Brasil, Conab. 47p. (Boletim, 12º Levantamento de grãos).). Although it is a very important crop in Brazil, its average productivity is still low, as the result of low technological level used in cultivation (Oliveira et al., 2015Oliveira LM, Schuch LOB, Bruno R, & Peske ST (2015) Qualidade de sementes de feijão-caupi tratadas com produtos químicos e armazenadas em condições controladas e não controladas de temperatura e umidade. Semina: Ciências Agrárias, 36:1263-1275.).

As a limiting factor for cowpea cultivation, it is possible to verify the difficulty in obtaining seeds with good physiological and sanitary quality, since these are considered one of the main inputs of agricultural production, acting as a preponderant factor to obtain uniform and vigorous plant stands, interfering directly with productivity (Nogueira et al., 2014Nogueira NW, Freitas RMO, Torres SB, & Leal CCP (2014) Physiological maturation of cowpea seeds. Journal of Seed Science, 36:312-317.).

By the way, the control of microorganisms associated with seeds is an essential measure to guarantee high productivity, which seed microbiolization has become an important study for researchers (Cruz et al., 2020Cruz JMFL, Medeiros ECD, Farias ORD, Silva ECD, & Nascimento LCD (2020) Microbiolization of organic cotton seeds with Trichoderma sp. and Saccharomyces cerevisiae. Journal of Seed Science, 42:01-09.; De Sá et al., 2019De Sá MNF, Lima JS, Jesus FN, & Perez JO (2019) Microbiolização na qualidade de sementes e crescimento inicial de plantas de Vigna unguiculata L. Walp. Acta Brasiliensis, 3:111-115.; Farias et al., 2019Farias OR, Nascimento LCD, Cruz JMFL, Silva HAO, Mello MDDO, Bruno RDLA, & Arriel NHC (2019) Biocontrol Potential of Trichoderma and Bacillus Species on Fusarium oxysporum f. sp vasinfectum. Journal of Experimental Agriculture International, 34:01-11.; Pereira et al., 2019Pereira FT, Oliveira JB, Muniz PHP, Peixoto GHS, Guimarães RR, & Carvalho DDC (2019) Growth promotion and productivity of lettuce using Trichoderma spp. commercial strains. Horticultura Brasileira, 37:69-74.), once it has reached out prominence in relation to synthetic products to be an alternative in reducing environmental risks caused by the excessive use of pesticides, thus aiming the use of microorganisms that are able to promote growth and direct action in the control of phytopathogens associated with seeds.

In the biological control of phytopathogens, Trichoderma spp. stands out due to its bioprotective action against the attack of pathogens during germination, promoting initial seedling growth, as well as the solubilization of insoluble micronutrients in the soil, increasing the vigor and yield of plants (Missio et al., 2016Missio EL, Moro T, Brum DL, Pollet CS, & Muniz MFB (2016) Vigor e germinação de sementes de Jacaranda mimosifolia d. don. (Bignoniaceae) após o tratamento e armazenamento. Caderno de Pesquisa, 28:42-53.; Gomes et al., 2019Gomes CDL, Sá JM, Rodrigues MHBS, Sousa VFO, & Bomfim MP (2019) Production of Tamarindus indica L. seedlings submitted to substrates and pre-germination methods. Pesquisa Agropecuária Tropical, 49:54029.).

For this reason, the aim of this work was to evaluate the initial growth and control of fungi associated with seeds of cowpea by the seed microbiolization with commercial strains of Trichoderma spp.

MATERIAL AND METHODS

The experiment was carried out in a completely randomized design, at the Phytopathology Laboratory (LAFIT) of the Department of Phytotechnics and Environmental Sciences at the Federal University of Paraíba (UFPB), with seeds of cowpea cultivar ‘BRS Gurguéia’ given by the Brazilian Agricultural Research Corporation (Embrapa) – Mid-North.

The commercial strains we used were T. asperellum T-211 (Trichodermax® EC, Novozymes BioAg Produtos para Agricultura Ltda), T. asperellum (Quality® WG URM-5911, Laboratory of BioControle Farroupilha Ltda), T. harzianum ESALQ -1306 (Trichodermil® SC, Koppert do Brasil Holding Ltda.), T. harzianum DSM 14944 (Agroguard® WG, Live Systems Technology S.A.) and T. harzianum IBLF 006 (Ecotrich® WP, Ballagro Agro Tecnologia Ltda).

The inoculation of seeds with strains of Trichoderma spp. was carried out following the methodology proposed by Carvalho et al. (2014)Carvalho DDC, Lobo Jr M, Martins I, Inglis PW, & Mello SCM (2014) Biological control of Fusarium oxysporum f. sp. phaseoli by Trichoderma harzianum and its use for common bean seed treatment. Tropical Plant Pathology, 39:384-391., in suspension of 2 mL 100g^-1 of seeds (2.5 x 10⁸ conidia mL^-1). The efficacy of the isolates, untreated seeds and treated seeds with fungicide carbendazim (100 mL 100 kg^-1 of seeds), was compared by using negative and positive controls, respectively.

The effect of seed microbiolization on the incidence of fungi was appraised by sanitary test (Blotter test) (Brasil, 2009Brasil (2009) Regras para análise de sementes. Brasília, MAPA. 395p.), using 200 seeds, divided into ten repetitions of twenty seeds, placed on Petri dishes (Ø 15 cm), under aseptic conditions, containing a double-layer of filter paper which was previously sterilized and moistened with sterile distilled water. The plates were incubated in a Biochemical Oxygen Demand (B.O.D) growth chamber for eight days, at constant temperature of 25 ± 2 °C with 12-hour photoperiod. We used optical microscope and specialized literature (Seifert et al., 2011Seifert K, Morgan-Jones G, Gams W, & Kendrick B (2011) The genera of Hyphomycetes. Utrecht, CBS-KNAW Fungal Biodiversity Centre. 866p.) to identify and assess the incidence of fungi associated with seeds, and results were expressed as percentage of the occurrence of fungi.

The initial seedling growth was evaluated by the germination and emergence tests, using four replications of 50 seeds. The emergency test was carried out in a greenhouse and seeds were sown in plastic trays of dimensions 66 x 33 x 6 cm, containing previously sterilized washed sand. For the germination test according to Brasil (2009)Brasil (2009) Regras para análise de sementes. Brasília, MAPA. 395p., seeds were distributed on previously sterilized Germitest® paper substrate and moistened with equivalent to 2.5 times the dry paper weight. After sowing, papers were wrapped in roll forms, placed inside transparent plastic bags and then taken to B.O.D., regulated at 25 ± 2 °C with 12-hour photoperiod.

The counting of germinated and emerged seeds, for the germination and emergence tests respectively, were performed daily from the fifth to the eight days after application of commercial strains (Brasil, 2009Brasil (2009) Regras para análise de sementes. Brasília, MAPA. 395p.). The first germination and emergence counts were done together with the tests, which allowed to calculate the germination and emergence speed indices (GSI and ESI, respectively), according to the formula proposed by Maguire (1962)Maguire JD (1962) Speed of germination aid in selection and evaluation of seedling emergence and vigor. Crop Science, 2:176-177..

The seedling length was measured by shoot lengths and the longest root lengths, with a digital caliper presenting an accuracy of 0.001 mm, and results were expressed in centimeters. Afterwards, we determined shoot and root dry matter of by a forced air circulation oven at 65 °C for 48 hours and then samples were weighed on an analytical balance with an accuracy of 0.001 g, and results were expressed in grams.

The electrical conductivity test was carried out thirty days after the application of treatments, using four replicates of 100 seeds, which were weighed and placed inside plastic glasses (200 mL), adding deionized water in the amount of 100 mL and subsequently kept in B.O.D. at temperature of 25 ± 2 °C. The electrical conductivity was determined after 12 and 24 hours and results were expressed in µS cm^-1 g^-1.

The statistical analysis was performed using the statistical software R (R Development Core Team, 2020R Development Core Team (2020) R: A Language and environment for statistical computing. Available at: https://www.R-project.org/. Accessed on: November 10th, 2020.
https://www.R-project.org/... ), results were submitted to normality test for residuals by Shapiro-Wilk and homogeneity of variances by Bartlett's test. The results that presented normal distribution and homoscedasticity were submitted to analysis of variance (ANOVA), and the means of the treatments were compared using the Tukey test (p ≤ 0.05). The values of the incidence of fungi were previously transformed into $\sqrt{\mathrm{y}}+1$.

RESULTS AND DISCUSSION

The effect of Trichoderma spp. commercial strains on the incidence of fungi is reported in Figure 1. Genera we identified were Aspergillus spp. (57.0%), Penicillium sp. (26.0%), Fusarium sp. (34.0%), Colletotrichum sp. (28.0%), Macrophomina sp. (27.0%).

Figure 1
Incidence of fungi associated with seeds of cowpea cultivar 'BRS Gurguéia' treated with commercial strains of Trichoderma spp. ASP – Aspergillus spp., PEN – Penicillium sp., FUS – Fusarium sp., COL – Colletotrichum sp., MAC – Macrophomina sp.

We verified that the application of Trichoderma spp. strains reduced the incidence of these fungi earlier mentioned. Results showed that no differences were verified between the action of antagonists when compared to the application of the fungicide carbendazim, with the exception of Trichoderma harzianum IBLF 006 (Ecotrich® WP) in the control of Penicillium sp., which means these strains were as efficient as the chemical treatment to control these microorganisms.

According to Singh et al. (2018)Singh A, Shukla N, Kabadwal BC, Tewari AK, & Kumar J (2018) Review on Plant-Trichoderma-Pathogen Interaction. International Journal of Current Microbiology and Applied Sciences, 7:2382-2397. modes of action of Trichoderma spp. that inhibit the growth of fungi may be several, such as mycoparasitism, which involves direct activity on phytopathogenic fungi, the antibiosis, antagonistic interaction involving low molecular weight diffusible secondary metabolites or antibiotics harmful to fungal phytopathogens; and the competition for substrate, which is the most important factor for the establishment of fungi in the search for space and nutrients.

These phytopathogenic genera we verified in seeds are keystone species responsible to cause diseases in cowpea (Amorim et al., 2016Amorim L, Rezende JAM, Bergamin Filho A, & Camargo LEA (2016) Manual de Fitopatologia: doença de plantas cultivadas. 5ª ed. Ouro Fino, Agronômica Ceres. 820p.), and they can be transmitted directly to seedlings, besides affecting directly seed quality, causing the loss of vigor, reduction of germination and signs of decay (Figure 2).

Figure 2
Seedlings of cowpea cultivar 'BRS Gurguéia' from the negative control infected by Aspergillus spp. (A) and (B), Penicillium sp. (C), Fusarium sp. (D), Colletotrichum sp. (E), Macrophomina sp. (F).

The variables of first germination (FGC) and emergency count (FEC), and root dry matter in the germination (RDMG) and emergence (RDME) did not show significant differences between the treatments applied.

In the germination speed index (GSI), T. harzianum ESALQ-1306 (Trichodermil®) and the fungicide were the highest, with values of 9.69 and 9.64 respectively, besides showing statistical differences in relation to the negative control. In the emergency speed index (ESI), T. asperellum T-211 (Trichodermax®) stood out, presenting 9.51, and it was the only treatment with significant difference in relation to the control treatment (Figure 3A).

Figure 3
The germination speed index (GSI), emergence speed index (ESI), germination percentage (GP) and emergence percentage (EP) from seeds of cowpea cultivar ‘BRS Gurguéia’ treated with commercial strains of Trichoderma spp. Columns with the same color and followed with similar letters do not differ statistically by Tukey test (p ≤ 0.05).

Regarding the germination percentage (GP), both strains of T. harzianum DSM 14944 (Agroguard®) and T. asperellum T-211 (Trichodermax®) differed from the control treatment and achieved 97.5% and 97.0% respectively (Figure 3B). For the emergency percentage (EP), only T. asperellum T-211 (Trichodermax®) showed difference when compared to the control treatment, with 94.5%.

This increase in germination potential associated with Trichoderma harzianum in beans has already been described by Carvalho et al. (2011)Carvalho DDC, Mello SCMD, Lobo Júnior M, & Geraldine AM (2011) Biocontrol of seed pathogens and growth promotion of common bean seedlings by Trichoderma harzianum. Pesquisa Agropecuária Brasileira, 46:822-828.. The results are associated with the release mechanism of plant growth regulator but also the solubilization of nutrients (Hajieghrari, 2010Hajieghrari B (2010) Effects of some Iranian Trichoderma isolates on maize seed germination and seedling vigor. African Journal of Biotechnology, 9:4342-4347.; Saber et al., 2017Saber WI, Ghoneem KM, Rashad YM, & Al-askar AA (2017) Trichoderma harzianum WKY1: an indole acetic acid producer for growth improvement and anthracnose disease control in sorghum. Biocontrol science and technology, 27:654-676.) that activate the production of enzymes and phytohormones involved in seed germination, thus increasing the germination speed and its vigor (Singh et al., 2018Singh A, Shukla N, Kabadwal BC, Tewari AK, & Kumar J (2018) Review on Plant-Trichoderma-Pathogen Interaction. International Journal of Current Microbiology and Applied Sciences, 7:2382-2397.).

Bezuidenhout et al. (2012)Bezuidenhout J, Van Rensburg L, & Jansen Van Rensburg P (2012) Molecular similarity between gibberellic acid and gliotoxin: unravelling the mechanism of action for plant growth promotion by Trichoderma harzianum. Journal of Agricultural Science and Technology, 6:703-712. reported the similarity of gliotoxin, secondary metabolite produced by T. harzianum, in relation to the gibberellic acid, plant growth hormone involved in the seed germination process, indicating a possible perception of gliotoxin as gibberellic acid, influencing the germination process positively.

We observed that the strain T. harzianum ESALQ-1306 (Trichodermil®) for the germination test had the shortest (5.15 cm) shoot length (SL) as well as the control treatment (4.33 cm). In the emergence, the fungicide and all the commercial strains of Trichoderma spp. showed the highest SL, differing from the control treatment (8.32 cm).

For the root length (RL) in the germination and emergence, T. harzianum IBLF 006 (Ecotrich®) was responsible for the highest root development of seedlings with 7.06 cm in germination and 14.18 cm in emergence, differing statistically from the control treatment, which presented the lowest RL value in the germination (5.70 cm) and emergence (11.33 cm) (Figure 4B). The chemical treatment and T. asperellum T-211 (Trichodermax®) also differed from the control treatment for RL in the germination.

Figure 4
Shoot length (SL) and root length (RL) from seeds of cowpea cultivar ‘BRS Gurguéia’ treated with commercial strains of Trichoderma spp. Columns with the same color and followed with similar letters do not differ statistically by Tukey test (p ≤ 0.05).

These results corroborate those reported by Pereira et al. (2019)Pereira FT, Oliveira JB, Muniz PHP, Peixoto GHS, Guimarães RR, & Carvalho DDC (2019) Growth promotion and productivity of lettuce using Trichoderma spp. commercial strains. Horticultura Brasileira, 37:69-74. that used strains similar to our research and found an increase for shoot and root growth in lettuce, thus evidencing the efficiency of the strains to promote the growth in cowpea.

Evaluating the shoot dry matter (SDM) in the germination, the strain T. harzianum IBLF 006 (Ecotrich®) achieve values of 0.048g and the fungicide of 0.045g, both differing significantly from the control treatment (0.028g) (Figure 5A). We also verified this difference in the emergency for the strains T. harzianum IBLF 006 (Ecotrich®), T. harzianum ESALQ-1306 (Trichodermil®) and T. asperellum URM-5911 (Quality®), with values of 0.100g, 0.098 and 0.095g respectively, and 0.060g for the control treatment, with lowest production of SDM.

Figure 5
Shoot dry matter (SDM) and electrical conductivity (EC) from seeds of cowpea cultivar ‘BRS Gurguéia’ treated with commercial strains of Trichoderma spp. Columns with the same color and followed with similar letters do not differ statistically by Tukey test (p ≤ 0.05).

The promotion of the initial plant growth is probably related to the mechanisms of indirect pathway, with growth inhibition of phytopathogens (Gava & Menezes, 2012Gava CAT, & Menezes MEL (2012) Eficiência de isolados de Trichoderma spp no controle de patógenos de solo em meloeiro amarelo. Revista Ciência Agronômica, 43:633-640.) and direct pathway, through the production of hormones or analogues (Saber et al., 2017Saber WI, Ghoneem KM, Rashad YM, & Al-askar AA (2017) Trichoderma harzianum WKY1: an indole acetic acid producer for growth improvement and anthracnose disease control in sorghum. Biocontrol science and technology, 27:654-676.) and phosphate solubilization (Oliveira et al., 2012Oliveira AG, Junior AF, Santos GR, Miller LO, & Chagas LFB (2012) Potencial de solubilização de fosfato e produção de AIA por Trichoderma spp. Revista Verde, 7:149-155.).

Trichoderma spp. is directly related to the balance of gibberellic acid, ethylene and mainly auxin by the production of indole-3-acetic acid (IAA), a hormone responsible for plant vegetative development, promoting cellular elongation, formation of secondary roots, production of apical and lateral buds (Oliveira et al., 2012Oliveira AG, Junior AF, Santos GR, Miller LO, & Chagas LFB (2012) Potencial de solubilização de fosfato e produção de AIA por Trichoderma spp. Revista Verde, 7:149-155.; Stewart & Hill, 2014Stewart A, & Hill R (2014) Applications of Trichoderma in plant growth promotion. In: Gupta VG, Schmoll M, Herrera-Estrella A, Upadhyay RS, Druzhinina I, & Tuohy M (Eds.) Biotechnology and biology of Trichoderma. Netherlands, Elsevier Science. p.415-428.).

Regarding electrical conductivity (EC), there is a positive activity with the application of Trichoderma spp. on seed vigor (Figure 5B). In the first 12 hours, the lowest values were verified for T. asperellum T-211 (Trichodermax®) and T. harzianum ESALQ-1306 (Trichodermil®), with 19.72 µS cm^-1g^-1 and 20.10 µS cm^-1 g^-1 respectively, both with statistical difference in relation to the control. In the 24-hour period, only T. harzianum IBLF 006 (Ecotrich®) and T. harzianum DSM 14944 (Agroguard®) did not differ statistically from the control treatment and the lowest values were 40.25 µS cm^-1 g^-1 and 40.92 µS cm^-1 g^-1, as well as in the first 12 hours, with strains T. harzianum ESALQ-1306 (Trichodermil®) and T. asperellum T-211 (Trichodermax®), respectively. The control showed the highest values than other treatments according to the periods of 12 (28.35 µS cm^-1 g^-1) and 24 hours (56.53 µS cm^-1 g^-1).

This change in electrical conductivity may be indirectly linked to the control of fungi associated with seeds, providing seed a greater protection in the integrity of cell membranes. Once seed quality is indirectly evaluated by the amount of leachate in the seed immersion solution in which, the least vigorous release greater amounts of solutes to the external environment (Machado et al., 2011Machado CG, Martins CC, Santana DG, Cruz SCS, & Oliveira SSC (2011) Adequação do teste de condutividade elétrica para sementes de Pisum sativum subsp Arvense. Ciência Rural, 41:988-995.; Marcos-Filho, 2015Marcos-Filho J (2015) Fisiologia de sementes de plantas cultivadas. 2ª ed. Londrina, Abrates. 659p.).

To sum up, electrical conductivity is able to detect seed deterioration in its initial growth, due to the integrity of cell membranes (Prado et al., 2019Prado JPD, Krzyzanowski FC, Martins CC, & Vieira RD (2019) Physiological potential of soybean seeds and its relationship to electrical conductivity. Journal of Seed Science, 41:407-415.). This quantification is essential, once seeds with lower vigor in the field have less vigorous seedlings and much difference in emergence when compared to seeds presenting higher vigor, because of the differences in seedling initial growth rates (Munizzi et al., 2010Munizzi A, Braccini AL, Rangel MAS, Scapim CA, & Albrecht LP (2010) Qualidade de sementes de quatro cultivares de soja, colhidas em dois locais no estado de Mato Grosso do Sul. Revista Brasileira de Sementes, 32:176-185.).

CONCLUSIONS

Seed microbiolization with Trichoderma asperellum and Trichoderma harzianum are effective in reducing the incidence of fungi and have antimicrobial activity similar to synthetic fungicide.

The strains T. asperellum T-211 (Trichodemax®), T. asperellum URM-5911 (Quality®) e T. harzianum ESALQ-1306 (Trichodermil®) promote increases for seed vigor.

The percentage of seed emergence is maximized with the application of strains T. asperellum (Quality® and Trichodemax®).

The commercial strains of Trichoderma tested increase the initial growth of cowpea seedlings cv. 'BRS Gurguéia'.

ACKNOWLEDGEMENTS, FINANCIAL SUPPORT AND FULL DISCLOSURE

We are grateful to Federal University of Paraíba (UFPB) and Federal University of Campina Grande (UFCG), for support in carrying out the research work. There is no conflict of interest or funding for publication of the manuscript.

REFERENCES

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