Global ETD Search

1	Observations on the fungi involved in the breakdown of beech and spruce in mixed woodland Fenwick, G. A. January 1997 (has links) No description available. 577 Wood degradation; Fungal culture
2	An investigation of selected effects of environment on the dry rot fungus, Serpula lacrymans Low, Gordon Alister January 2000 (has links) Comparisons were made between the sensitivities of unique ‘wild’ isolates and domestic isolates of the dry rot fungus, <i>Serpula lacrymans</i>, to temperature, water potential and pH. Comparisons were also made between their capacities of timber decay. The ‘wild’ Himalayan isolates displayed slightly less marked sensitivities to high and low temperature and lowered water potential, yet the isolates were equally tolerant of pH. In general, the linear growth rates of the domestic isolates proved to be twice those of the ‘wild’ Himalayan set, whereas little variation occurred between their rates of timber decay. This study also resulted in the first isolation and reliable identification of ‘wild-growing’ <i>S. lacrymans</i> collected in Europe. The main part of the project involved the construction of novel chambers in order to examine the effects of lowered humidity and moving air flow on the activity of <i>S. lacrymans</i>. In the smallest and simplest of these, its growth and timberdecaying activities could be stopped by incubation at 86% relative humidity or by the application of a pumped air flow rate of 2.5 litres per minute; however, <i>S. lacrymans</i> was not inactivated until more-stressful conditions were applied. In addition, an intermediate rate of air flow provoked marked directional growth away from the stress. Furthermore, the introduction of stone, brick and plaster into these models encouraged the capacities of timber decay and mycelial growth. The use of a larger and more representative model incorporating simulated flooring and plaster walling within glass tanks revealed differences in the appearances and patterns of colonisation by <i>S. lacrymans</i> depending upon whether aged or new materials were used. Treatments involving air drying by fans caused both a shrivelling and a loss of viability of the fungus only when there was no ‘reservoir’ of water available; when there was water present, latent activity remained. An elaboration of this experimental design tested the effects of a combined biological and environmental treatment. Subsequently, the application of <i>Trichoderma harzianum</i>, a known antagonist of <i>S. lacrymans</i>, proved not to be an effective remedial treatment on its own, but appeared to impart a mildly protective effect when combined with a drying regime. Importantly, in the latter situation <i>T. harzianum</i> caused a severe degradation of the part of the colony responsible for the uptake of water in <i>S. lacrymans</i>. Another workshop-scale model simulating more authentically a damp sub-floor space and a cavity behind aged plaster walling was developed. When respective treatments by fan drying and passive ventilation were compared, the former were more effective, but its efficacy could be augmented by incorporating low-level passive ventilation via discreet vents. In this manner, a successful remedial treatment of <i>S. lacrymans</i> could be effected, though the prevalence of mould could prove to be undesirable in practice. However, some samples of this displayed antagonistic effects against <i>S. lacrymans</i>. A further experiment was designed to test the effects of air drying on the production of the stress-protective carbohydrate trehalose and of some associated solutes by <i>S. lacrymans</i>. In contrast to reports of some other organisms, no definite stockpiling of any of the compounds occurred. A final series of experiments revealed that <i>S. lacrymans</i> removed calcium, silicon and iron from sandstone and calcium, sulphur and iron from aged plaster; these elements were sequestered on its hyphae, especially in the form of calcium oxalate. Degradation of the sandstone was implicit but not obvious microscopically. Furthermore, <i>S. lacrymans</i> transported iron from these building materials through its mycelial system. An attempt to determine the effects of separate minerals in sandstone and plaster on timber decay revealed few variations. 579 Mycology; Fungi; Wood degradation
3	A genomic and transcriptomic analysis of wood decay and copper tolerance in the brown rot fungus Fibroporia radiculosa Tang, Juliet D 09 December 2011 (has links) Brown rot fungi are notoriously copper-tolerant, which makes them difficult to control with copper-based wood preservatives. Brown rot fungi are also unique because they have evolved a bilateral strategy for decay. Their initial attack involves the production of hydroxyl free radicals to increase wood porosity, followed by an enzymatic onslaught of glycoside hydrolases that free the sugars locked within cellulose and hemicellulose. Our molecular understanding of these biological processes, however, has been hampered by our limited knowledge of the underlying genetic mechanisms. To address this knowledge gap, high-throughput, short-read sequencing was used to conduct a comprehensive analysis of the genomics and transcriptomics of wood decay and copper tolerance in the brown rot fungus Fibroporia radiculosa. The results were impressively informative. In the genomic study, the sequences of 9262 genes were predicted and gene function was assigned to 5407 of the genes. An examination of target motifs showed that 1213 of the genes encoded products with extracellular functions. By mining these genomic annotations, 187 genes were identified with putative roles in lignocellulose degradation and copper tolerance. The transcriptomic study quantified gene expression of the fungus growing on wood treated with a copper-based preservative. At day 31, the fungus was adapting to the preservative, and the wood showed no strength loss. At day 154, the preservative effects were gone, and the fungus was actively degrading the wood, which exhibited 52% strength loss. A total of 917 differentially expressed genes were identified, 108 of which appeared to be regulating wood decay and preservative tolerance. Genes that showed increased expression at day 31 were involved in oxalate metabolism, hydroxyl free radical production by the enzyme laccase, energy production, xenobiotic detoxification, copper resistance, stress response, and pectin degradation. Genes that exhibited higher expression at day 154 were involved in wood polysaccharide degradation, hexose transport, oxalate catabolism, catabolism of laccase substrates, proton reduction, re-modeling the glucan sheath, and shoring up the plasma membrane for acid shock. These newly discovered genes represent a significant step towards accelerating a genome-wide understanding of brown rot decay and tolerance to wood preservatives. systems biology wood degradation copper tolerance
4	Diversité fonctionelle des Glutation Transférases fongiques : caractérisation des classes Ure2p et GTT2 de Phanerochaete chrysosporium / Functional diversification of fungal Glutathione Transferases : characterization of Ure2p and GTT2 classes from Phanerochaete chrysosporium Thuillier, Anne 31 October 2013 (has links) Phanerochaete chrysosporium est un champignon forestier faisant partie des organismes saprophytes capables de recycler la matière organique morte. Grâce à l'excrétion de nombreuses enzymes de dégradation, en particulier des lignine peroxydases, il est capable de décomposer la matière végétale dont la lignine, un polymère complexe de composés phénoliques très résistant. L'élimination de la lignine permet la libération des autres composants du bois tels que la cellulose et l'hémicellulose qui peuvent être utilisés dans l'industrie papetière ou pour la production de bioéthanol de deuxième génération. La structure des intermédiaires et produits de dégradation de la lignine est souvent proche de celle denombreux polluants, d'où l'intérêt biotechnologique de P. chrysosporium dans les processus de bioremédiation. Cependant, les systèmes de dégradation engendrent des composés plus ou moins toxiques pour le champignon et contre lesquels il doit faire face. C'est pourquoi il possède un système de détoxication impliquant des enzymes telles que les cytochrome P450 monooxygénases ou encore les glutathion transférases (GST). Les Ure2p forment une classe de GST étendue chez Phanerochaete et d'autres basidiomycètes saprophytes. Leur étude par des approches phylogénétiques, biochimiques, structurales et transcriptomiques a permis de mieux comprendre les mécanismes d'évolution que peut subir une classe d'enzymes potentiellement soumises à une forte pression de sélection / Phanerochaete chrysosporium is a forest fungus being part of saprophytic organisms able to recycle dead organic matter. Thanks to the excretion of numerous wood decaying enzymes, and especially lignin peroxidases, this fungus is able to break down plant material including lignin, a complex polymer of phenolic compounds. Lignin removal allows the release of other wood components such as cellulose and hemicellulose, which can be further used in paper industry or to produce second generation bioethanol. The structure of intermediates and products from lignin decomposition is close to that of numerous pollutants making P. chrysosporium biotechnologically interesting for bioremediation purposes. Moreover, the fungus has to deal with more or less toxic compounds created by degradation mechanisms. It thus presents a detoxification pathway involving enzymes including cytochrome P450 monooxygenases and glutathione transferases (GST). Ure2p enzymes belong to an extended GST class in Phanerochaete genus as well as in other saprophytic basidiomycetes. Their study based on phylogenetic, biochemical, structural and transcriptomic approaches provides a better understanding of evolution mechanisms of a class of enzymes potentially subject to strong selection selection pressure Champignons saprophytes Dégradation du bois Glutathion transférases Xénobiotiques Détoxication Évolution Saprophytic fungi Wood degradation Glutathione transferases Xenobiotics Detoxification Evolution 579.5 572.792
5	Fungal Pigment Formation in Wood Substrate Tudor, Daniela 14 January 2014 (has links) A number of fungi produce spalted wood, which is characterized by accumulation of black pigment in fine demarcation lines, often accompanied by discoloration or staining on the wood fibers. Specific spalting fungi were identified by molecular analysis. From a total of 19 isolates and 140 clones studied, 11 fungal species were identified. The two Chlorociboria species from North America were investigated and their anamorphs were unambiguously identified for the first time. Fungal pigment formation under the influence of moisture content and pH variation was investigated in sugar maple, American beech and agar inoculated with spalting fungi. Maximum pigment production occurred at treatment with pH 4.5 for sugar maple and beech inoculated with Trametes versicolor. Xylaria polymorpha produced external pigmentation in beech treated with buffer at pH 5 and sugar maple at pH 4.5. Fungal pigmentation by Trametes versicolor and Xylaria polymorpha was stimulated at low moisture content in both wood species tested. Melanin production by Inonotus hispidus and Polyporus squamosus was stimulated above 22-28% and 34-38% moisture content in beech and in sugar maple respectively. Fomes fomentarius and Polyporus brumalis produced maximum pigmentation in beech at 26 - 41% and in sugar maple at 59 - 96% moisture content. The variation of the moisture content and pH values of wood substrates can stimulate the intensity of pigmentation of specific fungi in wood. To investigate melanin synthesis from a variety of melanin precursors, experimental research on three spalting fungi tested their reaction to catechol and L-Dopa melanin precursors in wood and agar substrate. The results indicate multiple biosynthesis pathways for melanin assembly in Trametes versicolor, Xylaria polymorha and Inonotus hispidus, and catechol produced most pigmentation in all spalting fungi investigated. Microscopic analysis by light, fluorescence, electron and confocal microscopy also indicates a bi- or multi-modal activity of melanin production and assembly by several spalting fungi. Possible variations of melanin assembly were identified based on fungal and wood species. Immunofluorescence and immunogold labelling with Mab 6D2 melanin antibody confirmed the melanin nature of the pigments produced by Oxyporus populinus, Trametes versicolor, Xylaria polymorpha, Fomes fomentarius, and Inonotus hispidus. spalting wood degradation staining fungi white rot fungi fungal melanin fungal pigment Trametes versicolor Xylaria plymorpha Chlorociboria Scytalidium cuboideum Wood technology 0746 Microbiology 0410
6	Fungal Pigment Formation in Wood Substrate Tudor, Daniela 14 January 2014 (has links) A number of fungi produce spalted wood, which is characterized by accumulation of black pigment in fine demarcation lines, often accompanied by discoloration or staining on the wood fibers. Specific spalting fungi were identified by molecular analysis. From a total of 19 isolates and 140 clones studied, 11 fungal species were identified. The two Chlorociboria species from North America were investigated and their anamorphs were unambiguously identified for the first time. Fungal pigment formation under the influence of moisture content and pH variation was investigated in sugar maple, American beech and agar inoculated with spalting fungi. Maximum pigment production occurred at treatment with pH 4.5 for sugar maple and beech inoculated with Trametes versicolor. Xylaria polymorpha produced external pigmentation in beech treated with buffer at pH 5 and sugar maple at pH 4.5. Fungal pigmentation by Trametes versicolor and Xylaria polymorpha was stimulated at low moisture content in both wood species tested. Melanin production by Inonotus hispidus and Polyporus squamosus was stimulated above 22-28% and 34-38% moisture content in beech and in sugar maple respectively. Fomes fomentarius and Polyporus brumalis produced maximum pigmentation in beech at 26 - 41% and in sugar maple at 59 - 96% moisture content. The variation of the moisture content and pH values of wood substrates can stimulate the intensity of pigmentation of specific fungi in wood. To investigate melanin synthesis from a variety of melanin precursors, experimental research on three spalting fungi tested their reaction to catechol and L-Dopa melanin precursors in wood and agar substrate. The results indicate multiple biosynthesis pathways for melanin assembly in Trametes versicolor, Xylaria polymorha and Inonotus hispidus, and catechol produced most pigmentation in all spalting fungi investigated. Microscopic analysis by light, fluorescence, electron and confocal microscopy also indicates a bi- or multi-modal activity of melanin production and assembly by several spalting fungi. Possible variations of melanin assembly were identified based on fungal and wood species. Immunofluorescence and immunogold labelling with Mab 6D2 melanin antibody confirmed the melanin nature of the pigments produced by Oxyporus populinus, Trametes versicolor, Xylaria polymorpha, Fomes fomentarius, and Inonotus hispidus. spalting wood degradation staining fungi white rot fungi fungal melanin fungal pigment Trametes versicolor Xylaria plymorpha Chlorociboria Scytalidium cuboideum Wood technology 0746 Microbiology 0410
7	Diversité structurale des Glutathion Transférases fongiques des classes Oméga et Xi et identification de leurs ligands par des approches cristallographiques / Structural diversity of fungal Xi and Omega glutathione transferases and identification of their ligands by crystallographic approaches Schwartz, Mathieu 25 September 2018 (has links) La détoxication est un processus biochimique présent chez tous les organismes biologiques et qui leur permet d’assurer leur survie face aux xénobiotiques provenant de leur environnement. Les glutathion transférases (GST) représentent une large famille d’enzymes participant à la phase II de détoxication en conjuguant le glutathion au composé à éliminer. Par ailleurs, certaines GST ont un rôle non catalytique et assurent la séquestration ou le transport de molécules d’un compartiment cellulaire à un autre. Alors que l’activité catalytique des GST est étudiée depuis plusieurs décades, l’identification précise des molécules physiologiques ciblées par les GST reste un défi. Chez les organismes fongiques dégradeurs de bois, certaines classes de GST se sont multipliées au niveau génomique. Cette redondance serait le reflet de la diversité des molécules chimiques libérées lors de la dégradation du bois. Dans cette thèse, des approches biochimiques et structurales ont été employées pour caractériser onze isoformes de GST du basidiomycète Trametes versicolor. De plus, une approche utilisant des librairies de molécules a permis d’identifier une famille de ligands reconnus par ces GST : les polyphénols. Les modes d’interaction de ces ligands ont été décrits précisément à partir de la résolution de nombreuses structures cristallographiques. L’identification d’un flavonoïde à partir d’un extrait de bois de merisier (Prunus avium), arbre sur lequel croît T. versicolor, a été permise par une approche de cristallographie d’affinité. Ces données suggèrent que les GST d’organismes fongiques saprotrophes pourraient prendre en charge les polyphénols libérés lors de la décomposition du bois / The ubiquitous biochemical process that enables each organism to cope with xenobiotics from its environment and thus ensures its survival is called detoxification. Glutathione transferases (GSTs) form a large family of enzymes divided into several classes. These enzymes participate in the detoxification phase II by conjugating the tripeptide glutathione to the molecule to be eliminated. Moreover, some GSTs are involved in non-catalytic processes such as sequestration or transport of molecules from one cellular compartment to another. Studies dedicated to the catalytic activity of GSTs have been ongoing for decades, yet precise identification of molecules targeted by GSTs remains challenging. In wood-decaying organisms, some of the GST classes have expanded with an increase of the number of isoforms encoded at the genomic level. This redundancy would reflect the diversity of the small molecules released upon wood enzymatic degradation. Through this thesis work, biochemical and structural approaches were used in order to characterize eleven GST isoforms from the saprotrophic fungus Trametes versicolor. In addition, the use of libraries of molecules helped in identifying polyphenols as a family of ligands that bind these GSTs. The molecular interaction modes were described precisely based on the resolution of numerous crystal structures. The identification of a flavonoid from an extract of the wild-cherry tree (Prunus avium) on which T. versicolor grows, was enabled by using an affinity crystallography approach. These data suggest that fungal GSTs could interact with plant polyphenols released during wood degradation Glutathion transférases Dégradation du bois Polyphénols Cristallographie aux rayons X Trametes versicolor Glutathione transferases Wood-degradation Polyphenols X-ray crystallography Trametes versicolor 547.632 572.792
8	Caractérisation fonctionnelle de petites protéines sécrétées chez les champignons lignolytiques / Characterization of small proteins by lignolytic fungi Valette, Nicolas 06 December 2017 (has links) Durant ces dernières décennies, les systèmes enzymatiques de dégradation du bois sécrétés par les champignons ont fait l’objet de nombreuses études aboutissant à la caractérisation fonctionnelle et biochimique des enzymes extracellulaires majeures agissant directement sur le polymère. Cependant, les systèmes annexes associés au processus de dégradation n’ont à l’heure actuelle été que peu étudiés. En particulier, les systèmes de détoxication et de réponses des champignons au stress généré par le processus de dégradation ainsi que les mécanismes lui permettant de croître dans cet environnement hostile sont encore peu connus. Ce stress est majoritairement dû à la présence de radicaux et d’extractibles. Les extractibles sont des molécules issues du métabolisme secondaire de l’arbre qui sont synthétisés pour augmenter la durabilité du bois face aux attaques biotiques et abiotiques. Une analyse transcriptomique réalisée au laboratoire a mis en évidence la surexpression de gènes codant des petites protéines sécrétées (SSP) chez Phanerochaete chrysosporium lors d’une culture en présence d’extractibles de chêne. La fonction de ce type de protéines chez les champignons lignolytiques est inconnue. Mon projet de thèse a porté sur la caractérisation d’une de ces SSP (SSP1). Les résultats obtenus ont révélé des propriétés biochimiques atypiques pour cette protéine qui est capable de former une structure fibrillaire, notamment grâce à la présence d’un domaine C-terminal riche en alanine et glycine. De plus, nous avons pu montrer que cette protéine présentait une activité β-glucuronidase in vitro, qui est dépendante de son état d’oligomérisation. Une approche physiologique a également été abordée grâce à l’obtention de mutants knock-out de SSP de Podospora anserina. La caractérisation de ces mutants a montré un défaut de croissance en condition de stress oxydant et en présence de molécules perturbant l’intégrité de la paroi cellulaire. Enfin, une analyse in silico des orthologues de SSP1 a montré la présence de ce gène dans les génomes d’organismes saprophytes, ectomycorhiziens ou pathogènes suggérant un rôle indirect de cette protéine dans les processus de dégradation du bois, probablement en lien avec la gestion du stress associé / During the last decades, the enzymatic systems involved in wood degradation have been intensively studied in fungi. This has led to functional and biochemical characterization of the main extracellular enzymes that are involved in the process. However, other systems associated to the degradation mechanisms have been poorly studied. In particular, the detoxification and stress response pathways allowing the fungus to grow in and resist the toxic conditions that are associated to the degradative process are still unknown. This stress is mostly due to the presence of radicals and extractives. Extractives are putative toxic compounds produced as secondary metabolites in tree to enhance wood durability against biotic and abiotic attacks. A transcriptomic analysis performed in the laboratory highlighted the up-regulation of genes coding for small secreted proteins (SSP) in Phanerochaete chrysosporium in presence of oak extractives. The functions of these SSP are unknown in lignolytic fungi. My PhD project was focused on the characterization of one of these SSP (namely SSP1) of P. chrysosporium. The biochemical data revealed atypical features for SSP1. Indeed, it is able to form fibrilar structure, thanks to an alanine-rich and glycine-rich C-terminal domain. Moreover, we have shown that this protein exhibits β-glucuronidase activity in vitro which is dependent on its oligomerization state. Physiological data were obtained thanks to the obtention of SSP knock-out mutants in Podospora anserina. These mutants have growth defect in oxidizing stress condition and in presence of cell wall-disruptive compounds. Finally, the in silico analysis of SSP1 orthologues revealed the presence of this gene in genomes of saprophytic, ectomycorrhizal or pathogenic fungi, suggesting an indirect role of this protein in wood degradation processes, probably linked to the associated stress Phanerochaete chrysosporium Petites protéines sécrétées (SSP) Dégradation du bois Extractibles Saprophytes Stress Phanerochaete chrysosporium Small secreted proteins (SSP) Wood degradation Extractives Saprophytic fungi Stress 579.17 579.5
9	Exploitation et exploration de la diversité génétique d’une population naturelle de Streptomyces issue d’un micro-habitat sol / Exploitation and exploration of the genetic diversity of natural population of Streptomyces from a soil micro-habitat Toussaint, Maxime 12 February 2018 (has links) Les Streptomyces possédent un large arsenal enzymatique ayant des rôles importants dans le sol. Au cours de cette thèse, nous avons exploré leur diversité génétique, fonctionnelle et écologique à partir de collections provenant de sols forestiers. Ainsi, l’exploration du potentiel cellulolytique et la capacité à détecter des sucres libérés lors de l’attaque du bois par des champignons lignivores a permis de créer un biosenseur dont l’exploitation pourrait constituer un nouvel outil normatif pour la détection de la dégradation du bois. Suite à une approche de génomique comparative réalisée entre des isolats sympatriques, nos résultats ont permis de démontrer que des souches phylogénétiquement très apparentées présentaient de grandes différences en termes de présence/absence de gènes, suggérant une vitesse d’évolution rapide du génome accessoire au sein de la population. Ces gènes, souvent associés à des éléments potentiellement transférables, a souligné un rôle important du transfert horizontal pour la diversification de la population. Par une approche d’écologie réverse, la fonction prédite de certains de ces gènes a également pu être corrélée avec un rôle écologique potentiel. Ainsi, l’un des clusters de gènes variables identifié était impliqué dans la production de métabolites secondaires et pourrait constituer un bien commun pour la population. Nos résultats ont confirmé la grande diversité métabolique des Streptomyces (et leur utilité à des fins appliquées), mais indique également qu’une diversification rapide entre souches proches, aurait un rôle écologique important au niveau des populations naturelles de Streptomyces / Streptomyces are known to possess a large enzymatic arsenal which can have important roles in the soil. During this thesis, we explored their genetic, functional and ecological diversity using collections from forest soils. Thus, the exploration of their cellulolytic potential and their ability to detect complex sugars released by wood during lignivorous fungi attacks has led to the creation of a biosensor whose exploitation could constitute a new normative tool for the detection of the degradation of wood. Subsequent to comparative genomic approach carried out between sympatric isolates, our results also demonstrated that phylogenetically highly related strains exhibited large differences in the presence / absence of genes, suggesting a rapid rate of evolution of the population accessory genome. These genes, often associated with potentially transferable elements, underlined important role of horizontal transfer for population diversification. Using a reverse ecology approach, the predicted function of some of these genes could also be correlated with a potential ecological role. Thus, one of the variable gene clusters identified by genome analysis was involved in the production of secondary metabolites and would constitute a common good for the population. All of our results confirm the wide metabolic diversity of Streptomyces (and their utility for applied purposes), but also indicates that this diversification would be rapid between nearby strains and would have an important ecological role in the natural populations of Streptomyces Bactéries du sol Streptomyces Micro-habitat Dégradation du bois Biosenseur Diversité génétique et métabolique Soil bacteria Streptomyces Micro-habitat Wood degradation Biosensor Genetic and metabolic diversity 579.175 7
10	The Role of Low-Molecular Weight Fungal Metabolites in Eutypa Dieback Grapevine Trunk Disease Sebestyen, Dana 20 October 2021 (has links) Eutypa dieback, one of several grapevine trunk diseases (GTDs), is of serious concern to the grape industry globally. This disease is caused by the fungus Eutypa lata but it is often seen in consortia growth with Phaeoacremonium minimum and Phaeomoniella chlamydospora. It is vital to understand the mechanisms for how this disease functions to develop control measures to combat it. Brown rot fungi are able to use a complex of low molecular weight (LMW) metabolites to induce a Fenton reaction to deconstruct woody tissue. These metabolites are part of a chelator mediated Fenton (CMF) chemistry that produces reactive oxygen species that are capable of depolymerizing wood polymers. We propose that a mechanism similar to CMF chemistry may be occurring in grapevine trunk disease pathogens. This thesis investigates how LMW metabolites produced by the fungi contribute to the disease and decay progression in GTDs. Research on Mite control in the laboratory with abamectin was also investigated, as research in this area was required when mites infested our fungal cultures and suitable laboratory controls were not available. Research on the GTD fungi was initiated by first examining whether metabolites produced by the three fungi can function in a manner to promote reactions like the CMF system. We separated and identified specific metabolites that potentially could contribute to CMF chemistry. We found that all three GTD fungi were able to produced LMW metabolites that promoted CMF chemistry, and we hypothesized that this mechanism contributes to processes leading to tissue necrosis in grapevine trunk wood. To explore the development of effective control measures based on this newly discovered mechanism for pathogenesis, we also explored the use of antioxidant/chelator compounds, BHA and BHT, in the control of the consortia fungi. Biocontrol organisms, Bacillus subtilis and Trichoderma atroviride, that produce antioxidants were also tested as biocontrols against the fungi involved in Eutypa Dieback disease. We found that BHA was highly effective in inhibiting fungal growth for all three fungi at concentrations higher than 0.5mM, and both B. subtilis and T. atroviride proved to be effective biocontrol agents in inhibiting E. lata, P. minimum, and P. chlamydospora. Grapevine trunk disease (GTD) Chelator-mediated Fenton chemistry (CMF) hydroxyl radicals wood degradation wood pathogens low molecular weight metabolites (LMW) Agricultural Science Microbial Physiology Microbiology Other Microbiology Plant Pathology

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