Alternaria solani responsible for early blight of eggplant is a worldwide spread notably in Iraq. The use of biological control agents represents the best alternative and eco-friendly approach. Two soil-borne fungal (Paecilomyces lilacinus and Trichoderma harzianum) were tested in laboratory conditions using the dual confrontation technique at different concentrations of conidia filtrate (10, 20 and 30% conidia/mL) and in vivo as potential bio-agents against A. solani. T. harzianum possessed the highest antifungal potency against A. solani with an inhibition rate above 50% at a concentration of 30% conidia/mL. In greenhouse experiments, both P. lilacinus and T. harzianum treated preventively on eggplant leaves inoculated with A. solani lowered significantly the disease severity index (31.61% and 28.08%, respectively). Obtained results revealed an augmentation of the peroxidase activity (4.84 units/g/mL/min for P. lilacinus; 3.88 units/g/mL/min for T. harzianum) in comparison with positive and negative controls. The effect of these two antagonists is limited not only to the protection of eggplant plants but also to the improvement of their growth by increasing the fresh (27.01% for P. lilacinus and 34.45% for T. harzianum) and dry weights (3.31% for P. lilacinus and 5.90% for T. harzianum) of the above-ground portion. Based on our results, we can conclude that T. harzianum could be recommended for biological control use.

Adhikari, P., Y. Oh and D. R. Panthee. 2017. Current status of early blight resistance in tomato: An update. International Journal of Molecular Sciences, 18: 1-22.

Alfiky, A. and L. Weisskopf. 2021. Deciphering Trichoderma-plant-pathogen interactions for better development of biocontrol applications. Journal of Fungi, 7: 1-18.

Benitez, T., A. M. Rincon, M. C. Limon and A. C. Codon. 2004. Biocontrol mechanism of Trichoderma strains. International Microbiology. 7: 249-260.

Chohan, S., R. Perveen, M. Anees, M. Azeem and M. Abid. 2019. Estimation of secondary metabolites of indigenous medicinal plant extracts and their in vitro and in vivo efficacy against tomato early blight disease in Pakistan. Journal of Plant Diseases and Protection, 126: 553-563.

Chohan, S., R. Perveen, M. A. Mehmood, S. Naz and N. Akram. 2015. Morpho-physiological studies, management and screening of tomato germplasm against Alternaria solani, the causal agent of tomato early blight. International Journal of Agriculture and Biology, 17: 112-118.

Deborah, S. D., A. Palaniswami, P. Vidhyasekaran and R. Velazhahan. 2001. Time course study of the induction of defense enzymes, phenolics and lignin in rice in response to infection by pathogen and non-pathogen. Journal of Plant Diseases and Protection, 108: 204-216.

El-Debaiky, S. A. E. K. 2018. Effect of the new antagonist; Aspergillus piperis on germination and growth of tomato plant and early blight incidence caused by Alternaria solani. Merit Research Journal of Agricultural Science and Soil Science, 6: 41-49.

El-Tanany, M. M., M. A. Hafez, G. A. Ahmed and M. H. Abd El-Mageed. 2018. Efficiency of biotic and abiotic inducers for controlling tomato early blight disease. Middle East Journal of Agriculture Research, 7: 650-670.

Esh, A. M. H., M. M. M. Atia, M. R. A. Tohamy and S. Taghian. 2011. Systemic resistance in sugar beet eliciated by non-pathogenic, phyllosphere-colonizing Bacillus pumilus and B. subtilus against the pathogen Cercospora beticola sacc. Journal of Plant Protection and Pathology, 2: 67-83.

Fontenelle, A. D. B., S. D. Guzzo, C. M. M. Lucon and R. Harakava. 2011. Growth promotion and induction of resistance in tomato plant against Xanthomonas euvesicatoria and Alternaria solani by Trichoderma spp. Crop Protection, 30: 1492-1500.

Hibar, K., M. Daami-Remadi, H. Khiareddine and M. El-Mahjoub. 2005. Effet inhibiteur in vitro et in vivo du Trichoderma harzianum sur Fusarium oxysporum f. sp. radicis-lycopersici. Biotechnologie, Agronomie, Société et Environnement, 9: 163-171.

Iram, W., T. Anjum, R. Jabeen and M. Abbas. 2018. Isolation of stored maize mycoflora, identification of aflatoxigenic fungi and its inhibition using medicinal plant extracts. International Journal of Agriculture and Biology, 20: 2149-2160.

Jindo, K., A. Evenhuis, C. Kempenaar, C. Pombo-Sudré, X. Zhan, M. Goitom-Teklua and G. Kessel. 2021. Review: Holistic pest management against early blight disease towards sustainable agriculture. Pest Management Science, 1-10.

Magesh, M. and P. Ahiladevi. 2017. Management of leaf blight through induction of defense enzyme in tomato. Plant Archives, 17: 935-940.

Matrood, A. A. A., M. I. Khrieba and O. G. Okon. 2020. Synergistic Interaction of Glomus mosseae T. and Trichoderma harzianum R. in the Induction of Systemic Resistance of Cucumis sativus L. to Alternaria alternata (Fr.) K. Plant Science Today, 7: 1-8.

Matrood, A. A. A., C. A. Ramírez Valdespino, M. A. Al-Waeli, M. I. Khrieba and A. Rhouma. 2021. Pathogenicity and chemical control of Alternaria sp. on date palm (Phoenix dactylifera L.). Plant Science Today, 8: 386-391.

Matrood, A. A. A. and A. Rhouma. 2021. Penicillium and Aspergillus species characterization: Adaptation to environmental factors and sensitivity to aqueous medicinal plants extracts. Review of Plant Studies, 8(1): 1-11.

Moreno-Gavíra, A., V. Huertas, F. Diánez, B. Sánchez-Montesinos and M. Santos. 2020. Paecilomyces and its importance in the biological control of agricultural pests and diseases. Plants, 9: 1-28.

Niño-Medina, G., V. Urías-Orona, M. D. Muy-Rangel and J. B. Heredia. 2017. Structure and content of phenolics in eggplant (Solanum melongena) a review. South African Journal of Botany, 111: 161-169.

Olivia-Devi, N., N. I. Singh, R. K. T. Devi and W. T. Chanu. 2017. In vitro evaluation of Alternaria solani (Ellis and Mart.) Jones and grout causing fruit rot of tomato by plant extracts and bio-control agents. International Journal of Current Microbiology and Applied Sciences, 6: 652-661.

Rhouma, A., I. B. Salem, N. B. M. Hamdi and J. I. R. G. Gomez. 2016. Efficacy of two fungicides for the management of Phytophthora infestans on potato through different applications methods adopted in controlled conditions. International Journal of Applied and Pure Science and Agriculture, 2: 39-45.

Rhouma, A., I. B. Salem, M. M. Hamdi and N. B. Hamdi. 2018. Antagonistic potential of certain soilborne fungal bioagents against Monosporascus root rot and vine decline of watermelon and promotion of its growth. Novel Research in Microbiology Journal, 2: 85-100.

Rhouma, A., I. Mougou and H. Rhouma. 2020. Determining the pressures on and risks to the natural and human resources in the Chott Sidi Abdel Salam oasis, southeastern Tunisia. Euro-Mediterranean Journal for Environmental Integration, 5: 37.

Roy, C. K., N. Akter, M. K. I. Sarkar, M. Uddin Pk, N. Begum, E. A. Zenat and M. A. A. Jahan. 2019. Control of early blight of tomato caused by Alternaria solani and screening of tomato varieties against the pathogen. The Open Microbiology Journal, 13: 41-50.

Salih, Y. A. and R. J. Abdul Ridha. 2019. A study of eggplant leaf spot disease in greenhouses at Basra Province. Basrah Journal of Agricultural Sciences, 32: 1-14.

Selim, M. E. 2015. Effectiveness of Trichoderma biotic applications in regulating the related defense genes affecting tomato early blight disease. Journal of Plant Pathology & Microbiology. 6: 6-10.

Sharon, E., M. Bar-Eyal, I. Chet, A. Herrera-Estrella, O. Kleifeld and Y. Spiegel. 2001. Biological control of root-knot nematode Meloidogyne javanica by Trichoderma harzianum. Phytopathology, 7: 687-693.

Varma, P. K., S. K. Gandhiand and S. Surender. 2008. Biological control of Alternaria solani, the causal agent of early blight of tomato. Journal of Biological Control, 22: 67-72.

Velazhahan, R. and P. Vidhyasekaran. 1994. Role of phenolic compounds, peroxidase and polyphenol-oxidase in resistance of groundnut to rust. Acta Phytopathologica et Entomologica Hungarica, 29: 23-29.

Viriyasuthee, W., S. Jogloy, W. Saksirirat, S. Saepaisan, M. L. Gleason and R. Shyang-Chen. 2019. Biological control of Alternaria leaf spot caused by Alternaria spp. in Jerusalem artichoke (Helianthus tuberosus L.) under two fertilization regimes. Plants, 8: 1-15.