Back Article

Liu J, Sui Y, Wisniewski M, Xie Z, Liu Y, et al. 2018. The impact of the postharvest environment on the viability and virulence of decay fungi. Critical Reviews in Food Science and Nutrition 58:1681−87

Navale V, Vamkudoth KR, Ajmera S, Dhuri V. 2021. Aspergillus derived mycotoxins in food and the environment: prevalence, detection, and toxicity. Toxicology Reports 8:1008−30

Abramson D. 2020. Toxicants of the genus Penicillium. In Handbook of plant and fungal toxicants, ed. D'Mello JPF. 1^st Edition. Boca Raton: CRC Press. pp. 303–17. doi: 10.1201/9780429281952-21

Bi K, Liang Y, Mengiste T, Sharon A. 2022. Killing softly: a roadmap of Botrytis cinerea pathogenicity. Trends in Plant Science 28:211−22

Summerell BA. 2019. Resolving Fusarium: current status of the genus. Annual Review Of Phytopathology 57:323−39

Aichinger G, Del Favero G, Warth B, Marko D. 2021. Alternaria toxins—still emerging? Comprehensive Reviews in Food Science and Food Safety 20:4390−406

Oghaz NA, Hatamzadeh S, Rahnama K, Moghaddam MK, Vaziee S, et al. 2022. Adjustment and quantification of UV–visible spectrophotometry analysis: an accurate and rapid method for estimating Cladosporium spp. spore concentration in a water suspension. World Journal of Microbiology and Biotechnology 38:183

Oyom W, Li YC, Prusky D, Zhang Z, Bi Y, et al. 2022. Recent advances in postharvest technology of Asia pears fungi disease control: A review. Physiological and Molecular Plant Pathology 117:101771

Rani L, Thapa K, Kanojia N, Sharma N, Singh S, et al. 2021. An extensive review on the consequences of chemical pesticides on human health and environment. Journal of Cleaner Production 283:124657

Corkley I, Fraaije B, Hawkins N. 2022. Fungicide resistance management: maximizing the effective life of plant protection products. Plant Pathology 71:150−69

Jahantigh S, Oghaz NA, Rahnama K, Hatamzadeh S. 2023. Application of Lactobacillus spp. for the biological management of green mold (Penicillium digitatum) on sweet orange fruit under in vitro and storehouse conditions. Biocontrol Science and Technology 33:567−81

Hatamzadeh S, Akbari Oghaz N, Rahnama K, Noori F. 2024. Comparison of the antifungal activity of chlorine dioxide, peracetic acid and some chemical fungicides in post-harvest management of Penicillium digitatum and Botrytis cinerea infecting sweet orange and strawberry fruits. Agricultural Research 13:72−84

Oghaz NA, Rahnama K, Habibi R, Razavi SI, Farias ARG. 2024. Endophytic and rhizospheric Trichoderma spp. associated with cucumber plants as potential biocontrol agents of Fusarium oxysporum f. sp. cucumerinum. Asian Journal of Mycology 7:31−46

Guzmán-Guzmán P, Kumar A, de Los Santos-Villalobos S, Parra-Cota FI, Orozco-Mosqueda MdC, et al. 2023. Trichoderma species: our best fungal allies in the biocontrol of plant diseases—a review. Plants 12:432

Schuster A, Schmoll M. 2010. Biology and biotechnology of Trichoderma. Applied Microbiology and Biotechnology 87:787−99

Dubey SC, Tripathi A, Dureja P, Grover A. 2011. Characterization of secondary metabolites and enzymes produced by Trichoderma species and their efficacy against plant pathogenic fungi. Indian Journal of Agricultural Sciences 81:455−61

Khan IH, Javaid A. 2020. In vitro biocontrol potential of Trichoderma pseudokoningii against Macrophomina phaseolina. International Journal of Agriculture and Biology 24:730−36

Zhang JL, Tang WL, Huang QR, Li YZ, Wei ML, et al. 2021. Trichoderma: a treasure house of structurally diverse secondary metabolites with medicinal importance. Frontiers in Microbiology 12:723828

Siddiquee S, Cheong BE, Taslima K, Kausar H, Hasan MM. 2012. Separation and identification of volatile compounds from liquid cultures of Trichoderma harzianum by GC-MS using three different capillary columns. Journal of Chromatographic Science 50:358−67

Khan RAA, Najeeb S, Hussain S, Xie B, Li Y. 2020. Bioactive secondary metabolites from Trichoderma spp. against phytopathogenic fungi. Microorganisms 8:817

Risoli S, Cotrozzi L, Sarrocco S, Nuzzaci M, Pellegrini E, et al. 2022. Trichoderma-induced resistance to Botrytis cinerea in Solanum species: a meta-analysis. Plants 11:180

Vos CMF, De Cremer K, Cammue BPA, De Coninck B. 2015. The toolbox of Trichoderma spp. in the biocontrol of Botrytis cinerea disease. Molecular Plant Pathology 16:400−12

Barbosa MAG, Rehn KG, Menezes M, de Lima R Mariano R. 2001. Antagonism of Trichoderma species on Cladosporium herbarum and their enzimatic characterization. Brazilian Journal of Microbiology 32:98−104

Mironenka J, Różalska S, Soboń A, Bernat P. 2021. Trichoderma harzianum metabolites disturb Fusarium culmorum metabolism: metabolomic and proteomic studies. Microbiological Research 249:126770

Modrzewska M, Błaszczyk L, Stępień Ł, Urbaniak M, Waśkiewicz A, et al. 2022. Trichoderma versus Fusarium—inhibition of pathogen growth and mycotoxin biosynthesis. Molecules 27:8146

Sharma IP, Sharma AK. 2020. Trichoderma–Fusarium interactions: a biocontrol strategy to manage wilt. In Trichoderma: Host pathogen interactions and applications, ed. Sharma A, Sharma P. Singapore: Springer. pp. 167–85. doi: 10.1007/978-981-15-3321-1_9

Metz N, Hausladen H. 2022. Trichoderma spp. as potential biological control agent against Alternaria solani in potato. Biological Control 166:104820

Shafique S, Shafique S, Javed A, Akhtar N, Bibi S. 2019. Analysis of antagonistic potential of secondary metabolites and organic fractions of Trichoderma species against Alternaria Alternata. Biocontrol Science 24:81−88

Carratore RD, Gervasi PG, Contini MP, Beffy P, Maserti BE, et al. 2011. Expression and characterization of two new alkane-inducible cytochrome P450s from Trichoderma harzianum. Biotechnology Letters 33:1201−6

Liu XH, Song YP, Wang BG, Ji NY. 2021. Sesquiterpenes and lipids from the algicolous fungus Trichoderma atroviride RR-dl-3-9. Phytochemistry Letters 45:6−12

Zhang XF, Li QY, Wang M, Ma SQ, Zheng YF, et al. 2022. 2E,4E-decadienoic acid, a novel anti-oomycete agent from coculture of Bacillus subtilis and Trichoderma asperellum. Microbiology Spectrum 10:e01542-22

Ogbolu DO, Oni AA, Daini OA, Oloko AP. 2007. In vitro antimicrobial properties of coconut oil on Candida species in Ibadan, Nigeria. Journal of Medicinal Food 10:384−87

Tsuji Y, Torti SV, Torti FM. 1998. Activation of the ferritin H enhancer, FER-1, by the cooperative action of members of the AP1 and Sp1 transcription factor families. Journal of Biological Chemistry 273:2984−92

Walsh M, Whitlock R, Garg AX, Légaré JF, Duncan AE, et al. 2016. Effects of remote ischemic preconditioning in high-risk patients undergoing cardiac surgery (Remote IMPACT): a randomized controlled trial. CMAJ 188:329−36

Pinto MEA, Araújo SG, Morais MI, Sá NP, Lima CM, et al. 2017. Antifungal and antioxidant activity of fatty acid methyl esters from vegetable oils. Anais da Academia Brasileira de Ciências 89:1671−81

Chandrasekaran M, Senthilkumar A, Venkatesalu V. 2011. Antibacterial and antifungal efficacy of fatty acid methyl esters from the leaves of Sesuvium portulacastrum L. European Review for Medical and Pharmacological Sciences 15:775−80

Brown DE, Hasan M, Lepe-Casillas M, Thornton AJ. 1990. Effect of temperature and pH on lipid accumulation by Trichoderma reesei. Applied Microbiology and Biotechnology 34:335−39

Ruiz N, Dubois N, Wielgosz-Collin G, du Pont TR, Bergé JP, et al. 2007. Lipid content and fatty acid composition of a marine-derived Trichoderma longibrachiatum strain cultured by agar surface and submerged fermentations. Process Biochemistry 42:676−80

Prasath KG, Tharani H, Kumar MS, Pandian SK. 2020. Palmitic acid inhibits the virulence factors of Candida tropicalis: biofilms, cell surface hydrophobicity, ergosterol biosynthesis, and enzymatic activity. Frontiers in Microbiology 11:864

Chahal A, Monreal CM, Bissett J, Rowland O, Smith ML, et al. 2014. Metabolism of n-C10:0 and n-C11:0 fatty acids by Trichoderma koningii, Penicillium janthinellum and their mixed culture: I. Biomass and CO₂ production, and allocation of intracellular lipids. Journal of Environmental Science and Health, Part B 49:945−54

Serrano-Carreon L, Hathout Y, Bensoussan M, Belin JM. 1992. Production of 6-pentyl-α-pyrone by Trichoderma harzianum from 18: n fatty acid methyl esters. Biotechnology Letters 14:1019−24

Sreenayana B, Vinodkumar S, Nakkeeran S, Muthulakshmi P, Poornima K. 2022. Multitudinous potential of Trichoderma species in imparting resistance against F. oxysporum f. sp. cucumerinum and Meloidogyne incognita disease complex. Journal of Plant Growth Regulation 41:1187−206

Rossi A, Martins MP, Bitencourt TA, Peres NTA, Rocha CHL, et al. 2021. Reassessing the use of undecanoic acid as a therapeutic strategy for treating fungal infections. Mycopathologia 186:327−40

Lee JH, Kim YG, Khadke SK, Lee J. 2021. Antibiofilm and antifungal activities of medium-chain fatty acids against Candida albicans via mimicking of the quorum-sensing molecule farnesol. Microbial Biotechnology 14:1353−66

Avrahami D, Shai Y. 2003. Bestowing antifungal and antibacterial activities by lipophilic acid conjugation to ᴅ,ʟ-amino acid-containing antimicrobial peptides: a plausible mode of action. Biochemistry 42:14946−56

Angel LPL, Sundram S, Ping BTY, Yusof MT, Ismail IS. 2018. Profiling of anti-fungal activity of Trichoderma virens 159C involved in biocontrol assay of Ganoderma boninense. Journal of Oil Palm Research 30:83−93

Collins RP, Halim AF. 1972. Characterization of the major aroma constituent of the fungus Trichoderma viride. Journal of Agricultural and Food Chemistry 20:437−38

Huang R, Zhang F, Zhou H, Yu H, Shen L, et al. 2023. Characterization of Trichoderma reesei endoglucanase displayed on the Saccharomyces cerevisiae cell surface and its effect on wine flavor in combination with β-glucosidase. Process Biochemistry 124:140−49

Kabara JJ, Swieczkowski DM, Conley AJ, Truant JP. 1972. Fatty acids and derivatives as antimicrobial agents. Antimicrobial Agents and Chemotherapy 2:23−28

Schlembach I, Hosseinpour Tehrani H, Blank LM, Büchs J, Wierckx N, et al. 2020. Consolidated bioprocessing of cellulose to itaconic acid by a co-culture of Trichoderma reesei and Ustilago maydis. Biotechnology for Biofuels 13:207

Teleky B-E, Vodnar DC. 2021. Recent advances in biotechnological itaconic acid production, and application for a sustainable approach. Polymers 13:3574

Cordes T, Michelucci A, Hiller K. 2015. Itaconic acid: the surprising role of an industrial compound as a mammalian antimicrobial metabolite. Annual Review of Nutrition 35:451−73

Shaaban MT, Ghaly MF, Fahmi SM. 2021. Antibacterial activities of hexadecanoic acid methyl ester and green-synthesized silver nanoparticles against multidrug-resistant bacteria. Journal of basic microbiology 61:557−68

Mulatu A, Megersa N, Tolcha T, Alemu T, Vetukuri RR. 2022. Antifungal compounds, GC-MS analysis and toxicity assessment of methanolic extracts of Trichoderma species in an animal model. PLoS One 17:e0274062

Serrano-Carreón L, Balderas-Ruíz K, Galindo E, Rito-Palomares M. 2002. Production and biotransformation of 6-pentyl-α-pyrone by Trichoderma harzianum in two-phase culture systems. Applied Microbiology and Biotechnology 58:170−74

Hirpara DG, Gajera HP, Bhimani RD, Golakiya BA. 2016. The SRAP based molecular diversity related to antifungal and antioxidant bioactive constituents for biocontrol potentials of Trichoderma against Sclerotium rolfsii Scc. Current Genetics 62:619−41

Lee S, Yap M, Behringer G, Hung R, Bennett JW. 2016. Volatile organic compounds emitted by Trichoderma species mediate plant growth. Fungal Biology and Biotechnology 3:7

Daccò C, Nicola L, Temporiti MEE, Mannucci B, Corana F, et al. 2020. Trichoderma: evaluation of its degrading abilities for the bioremediation of hydrocarbon complex mixtures. Applied Sciences 10:3152

Dini I, Marra R, Cavallo P, Pironti A, Sepe I, et al. 2021. Trichoderma strains and metabolites selectively increase the production of volatile organic compounds (VOCs) in olive trees. Metabolites 11:213

Gajera HP, Hirpara DG, Savaliya DD, Golakiya BA. 2020. Extracellular metabolomics of Trichoderma biocontroller for antifungal action to restrain Rhizoctonia solani Kuhn in cotton. Physiological and Molecular Plant Pathology 112:101547

Pavirhra R, Lalitha S. 2020. Tetradecane producing biocontrol agent, Trichoderma spp. against Fusarium oxysporum in tomato (Solanum lycopersicum L.). International Journal of Agricultural Technology 16:1475−92

Zhan X, Khan RAA, Zhang J, Chen J, Yin Y, et al. 2023. Control of postharvest stem-end rot on mango by antifungal metabolites of Trichoderma pinnatum LS029-3. Scientia Horticulturae 310:111696

Shavkiev J, Kholmamatovich KH, Ismoilovna TB, Kizi ANS, Khodjakbarovich NM, et al. 2022. Some volatile metabolites produced by the antifungal-Trichoderma asperellum UZ-A4 micromycete. International Journal of Phytopathology 11:239−51

Filippovich SY, Bachurina GP. 2021. Nitric Oxide in Fungal Metabolism. Applied Biochemistry and Microbiology 57:694−705