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Erschienen in:
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2024 | OriginalPaper | Buchkapitel

Tomato Growth Promotion by Trichoderma Asperellum Laboratory-Made Bioproduct

verfasst von : Hanane E. L. Kaissoumi, Fadoua Berbera, Najoua Mouden, Abdelatif OuazzaniChahdi, Amina Ouazzani Touhami, Karima Selmaoui, Rachid Benkirane, Allal Douira

Erschienen in: Sustainable and Green Technologies for Water and Environmental Management

Verlag: Springer Nature Switzerland

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Abstract

The endophytic fungus Trichoderma asperellum known as biological control agent has also capacity to stimulate plant growth. Tomato plants were treated with the moroccan T. asperellum laboratory-made biofungicidal and biostimulant product slurry at a concentration of 107 conidia.mL−1 by dipping before planting and by fertigation with different volumes, 5 L, 10 L, 15 L and 20 L, three times every 20 days during cultivation. The tomato plants grew well compared to the control plants. The aerial part length, numbers of leaves, flowers and fruits respectively increased with time varying from 48.29 to 55.64/34.28 cm; 10.36 to 12.56/8.6; 6.86 to 9.72/5.2; 0 to 0.26/0 after the first application, from 79. 06 to 91.09/ 51.83 cm; 27.6 to 32.43/22.53; 23.9 to 42.4/9.8; 3.84–5.88/2.74 after the second application and from 95.55 to 112.12/70.53 cm; 39.92 to 45.62/22.48; 17.08 to 58.99/7.94; 14.32 to 23.2/12.14 after the third application. By the end of the trial, the root part length and the fresh weights of the aerial and root parts attained 53/48 cm; 555.96/238.3 g and 31.76/20.06 g respectively. T. asperellum was able to colonize the roots, stems and leaves of the tomato plants, with significant re-isolation percentages reaching 90%, 85% and 66.66%. The T. asperellum based bioproduct has shown its ability to promote the growth of tomato plants, the gain percentages of the different agronomic parameters are very important which can be multiplied by 2, 3 or even 5, as in some cases.

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Vorheriges Kapitel Measurement and Analysis of NO Concentration by Differential Optical Absorption Spectroscopy: Towards Enhanced Air Quality Monitoring
Nächstes Kapitel Integrated Control of Strawberry Anthrachnose by Trichoderma Asperellum–Pyraclostrobin/Boscalid Combination
Literatur
Arah IK (2015) An overview of post-harvest challenges facing tomato production in Africa. In: African Studies Association of Australasia and the Pacific (AFSAAP) 37th annual conference Africa: diversity and development. Dunedin, New Zealand, pp 1–21
Baker R, Elad Y, Chet I (1984) The controlled experiment in the scientific method with special emphasis on biological control. Phytopathology 74:1019–1021CrossRef
Brunner K, Zeilinger S, Ciliento R, Woo SL, Lorito M, Kubicek CP, Mach RL (2005) Improvement of the fungal biocontrol agent Trichoderma atroviride to enhance both antagonism and induction of plant systemic disease resistance. Appl Environ Microbiol 71:3959–3965CrossRef
Caron J, Laverdière L, Thibodeau PO, Bélanger RR (2020) Utilisation d’une souche indigène de Trichoderma harzianum contre cinq agents pathogènes chez le concombre et la tomate de serre au Québec. Phytoprotection 83:73–87CrossRef
Chang YC, Chang YC, Baker R, Kleifeld O, Chet I (1986) Increased growth of plants in the presence of the biological control agent Trichoderma harzianum. Plant Dis 70:145–148CrossRef
Chliyeh M, Ouazzani Chahdi A, Selmaoui K, Ouazzani Touhami A, Filali Maltouf A, El Modafar C, Moukhli A, Oukabli A, Benkirane R, Douira A (2014) Effect of Trichoderma and arbuscular mycorrhizal fungi againt verticillium wilt of tomato. Int J Recent Sci Res 5(2):449–459
Darles B (2013) Evaluation de l’efficacité de diffèrent produits de biocontrôle, pour lutter contre la fusariose du Dipladenia. Rapport de stage, (Bioingénierie) option Biotechnologie végétales, Université Paul Sabatier, Toulouse, pp 35
De Souza JT, Bailey BA, Pomella AWV, Erbe EF, Murphy CA, Bae H, Hebbar PK (2008) Colonization of cacao seedlings by Trichoderma stromaticum, a mycoparasite of the witches’ broom pathogen, and its influence on plant growth and resistance. Biol Contr 46:36–45CrossRef
Elame F, Lionboui H, Wifaya A, Mokrini F, Mimouni A, Azim K (2019) Revue Marocaine des Sciences Agronomiques et Vétérinaires 7(4):595–599
Elshafie HS, Sakr S, Bufo SA, Camele I (2017) An attempt of biocontrol the tomato-wilt disease caused by Verticillium dahlia using Burkholderia gladioli pv. agaricicola and its bioactive secondary metabolites. Int J Plant Biol 8:7263. https://​doi.​org/​10.​4081/​pb.​2017.​7263
Gravel V, Antoun H, Tweddell RJ (2007) Growth stimulation and fruit yield improvement of greenhouse tomato plants by inoculation with Pseudomonas putida or Trichoderma atroviride: possible role of indole acetic acid (IAA). Soil Biol Biochem 39:1968–1977CrossRef
Harman GE (2011) Trichoderma—not just for biocontrol anymore. Phytoparasitica 39:103–108CrossRef
Harman GE, Petzoldt R, Comis A, Chen J (2004) Interactions between Trichoderma harzianum strains T22 and maize inbred line mo 17 and effects of these interactions on diseases caused by Pythium ultimum and Colletotrichum graminicola. Phytopathology 94(2):147–153CrossRef
Heraux FMG, Hallett SG, Ragothama KG, Weller SC (2005) Composted chicken manure as a medium for the production and delivery of Trichoderma virens for weed control. Hort Sci 40:1394–1397
Hewedy OA, Abdel KS, lateif MF, Seleiman AS, Albarakaty FM, El-Meihy RM (2020b) Phylogenetic diversity of Trichoderma strains and their antagonistic potential against soil-borne pathogens under stress conditions. Biology 9:189. https://​doi.​org/​10.​3390/​biology9080189
Howell CR (2003) Mechanisms employed by Trichoderma species in the biological control of plant diseases: the history and evolution of current concepts. Plant Dis 87:4–10CrossRef
Jones JB, Zitter TA, Momol TM, Miller SA (2014) Compendium of tomato diseases and pests. APS Press, United States
Kleifeld O, Chet I (1992) Trichoderma harzianum—Interaction with plants and effect on growth response. Plant Soil 144:267–272
Mouria B, Ouazzani-Touhami A, Douira A (2007) Effet de diverses souches du Trichoderma sur la croissance d'une culture de tomate en serre et leur aptitude à coloniser les racines et le substrat Phytoprotection 88(3):103–110
Mulugeta T, Muhinyuza JB, Gous-Meyer R, Matsaunyane L, Andreasson E, Alexandersson E (2020) Botanicals and plant strengtheners for potato and tomato cultivation in Africa. J Integr Agric 19(2):406–427CrossRef
Ortiz A, Orduz S (2001) In vitro evaluation of Trichoderma and Gliocladium antagonism against the symbiotic fungus of the leaf-cutting and Attacephalots. Mycopathologia 150:53–60CrossRef
Ouazzani Chahdi A, Ouazzani Touhami A, Khirallah W, Benkirane R, Douira A (2019) Production, formulation et recyclage d'un produit biofongicide et biostimulant à base de Trichoderma asperellum. MA 41534 Date de publication, June 31. https://​patentregister.​ompic.​ma/​SearchPatent/​searchByDepot?​typeNum=​AP&​numDepot=​41534&​count=​0&​lang=​FR
Pal KK, Gardener BM (2006) Biological control of plant pathogens. American Psychopathological Society, St. Paul, MNCrossRef
Paulitz TC, Belanger RR (2001) Biological control in greenhouse systems. Annual Rev Phytopathol 39:103–133CrossRef
Ruiz-Cisneros MF, Ornelas-Paz JJ, Olivas-Orozco GI, Acosta-Muñiz CH, Sepúlveda-Ahumada DR, Pérez-Corral DA, Rios-Velasco C, Salas-Marina MA, Fernández-Pavía SP (2018) Effect of Trichoderma spp. and phytopathogenic fungi on plant growth and tomato fruit quality. Revista Mexicana de Fitopatologia 36(3):444–456
Rwomushana I, Beale T, Chipabika G, Day R, Gonzalez-Moreno P, Lamontagne Godwin J, Makale F, Pratt C, Tambo J (2019) Evidence note: tomato leafminet (Tuta absoluta): impacts and coping strategies for Africa. CABI Work. Paper 12:1–56
Sahebani N, Hadavi N (2008) Biological control of the root-knot nematode Meloidogyne javanica by Trichoderma harzianum. Soil Biol Biochem 40:2016–2020CrossRef
Sani Md NH, Hasan M, Uddain J, Subramaniam S (2020) Impact of application of Trichoderma and biochar on growth, productivity and nutritional quality of tomato under reduced N-P-K fertilization. Ann Agric Sci 65(1):107–115
Sehim AE, Hewedy OA, Altammar KH, Alhumaidi MS, Abd-Elghaffar RY (2023) Trichoderma asperellum empowers tomato plants and suppresses Fusarium oxysporum through priming responses. Front Microbiol 14:1140378CrossRef
Shanmugaiah V, Balasubramanian N, Gomathinayagam S, Manoharan PT, Rajendran A (2009) Effect of single application of Trichoderma viride and Pseudomonas fluorescens on growth promotion in cotton plants. Afr J Agric Res 4(11):1220–1225
Shivam M, Rai D, Rai B, Dubey S (2019) Growth promotion effect of Trichoderma Isolates on tomato seedlings. J Plant Dis Sci 14(2):115–118
Shoresh M, Harman GE, Mastouri F (2010) Induced systemic resistance and plant responses to fungal biocontrol agents. Ann Rev Phytopath 48:21–43CrossRef
Singh V, Upadhyay RS, Sarma BK, Singh HB (2016) Seed bio-priming with Trichoderma asperellum effectively modulate plant growth promotion in pea. Int J Agric, Environ Biotechnol 9(3):361–365CrossRef
Srivastava VK (2004) Trichoderma spp- a boon for better crop health. Pest 28(8):40–45
Szabó M, Csepregi K, Gálber M, Virányi F, Fekete C (2012) Control plant-parasitic nematodes with Trichoderma species and nematode-trapping fungi: the role of chi18-5 and chi18-12 genes in nematode egg-parasitism. Biol Contr 63(2):121–128CrossRef
Viesturs U, Leite M, Treimanis A, Eremeeva T, Apsite A, Eisimonte M, Jansons P (1996) Production of cellulases and xylanases by Trichoderma viride and biological processing of lignocellulose and recycled paper fibers. Appl Biochem Biotechnol 57:349–360CrossRef
Vinale F, Marra R, Scala F, Ghisalberti EL, Lorito M, Sivasithamparam K (2006) Major secondary metabolites produced by two commercial Trichoderma strains active against different phytopathogens. Lett Appl Microbiol 43:143–148CrossRef
Wang R, Chen D, Khan RAA, Cui J, Hou J, Liu T (2021) A novel Trichoderma asperellum strain DQ-1 promotes tomato growth and induces resistance to gray mold caused by Botrytis cinerea. FEMS Microbiol Lett 368(20):fnab140
Whipps JM, Lumsden RD (2001) Commercial use of fungi as plant disease biological control agent: status and prospects. In: Butt T, Jackson C, Magan N (eds) Fungal biocontrol agents progress, problems and potential. CAB Publishing, Wallingford, pp 9–22CrossRef
Windham MTY, Baker R (1986) A mechanism for increased plant growth induced by Trichoderma spp. Phytopathology 76:518–521CrossRef
Woo SL, Scala F, Ruocco M, Lorito M (2006) The molecular biology of the interactions between Trichoderma spp., phytopathogenic fungi, and plants. Phytopathology 96:181–185
Metadaten
Titel
Tomato Growth Promotion by Trichoderma Asperellum Laboratory-Made Bioproduct
verfasst von
Hanane E. L. Kaissoumi
Fadoua Berbera
Najoua Mouden
Abdelatif OuazzaniChahdi
Amina Ouazzani Touhami
Karima Selmaoui
Rachid Benkirane
Allal Douira
Copyright-Jahr
2024
Buch
Sustainable and Green Technologies for Water and Environmental Management

Print ISBN: 978-3-031-52418-9

Electronic ISBN: 978-3-031-52419-6

Copyright-Jahr: 2024

DOI
https://doi.org/10.1007/978-3-031-52419-6_13