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Characterisation of cellulases from anaerobic fungus Piromyces sp. strain KS11 /Smyth, Danielle Julianna. January 2004 (has links) (PDF)
Thesis (Ph.D.) - University of Queensland, 2006. / Includes bibliography.
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Developing Anaerobic Fungi As a platform for Efficient lignocellulose hydrolysisCasey A. Hooker (5930663) 04 January 2019 (has links)
<p>Lignocellulose is an ubiquitous source of fixed carbon that is presently underexploited for renewable energy technologies. Currently, producing enzyme cocktails that robustly degrade these feedstocks is a significant economic bottleneck. Anaerobic gut fungi native to the digestive tracts of ruminants and hindgut fermenters are widely understudied despite their inherent ability to degrade a significant portion (~50%) of the lignocellulose in herbivorous animals. Challenges in cultivation due to their strict oxygen sensitivity, and the lack of a central repository to maintain axenic stocks substantially impede the progress with anaerobic fungi. Yet, these microbes have evolved elegant strategies and may harbor novel biomass degrading enzymes that could be used to more efficiently hydrolyze lignocellulose. Developing these organisms through characterization and genome engineering will yield significant contributions to the bioenergy community by improving hydrolysis technologies.</p>
<p>In this work, we report the isolation of four novel species of anaerobic gut fungi. A more complete characterization of one of our four fungal isolates is investigated, whereby the effects of substrate composition and the corresponding fungal growth rates are compared. I also explore the growth of one of our fungal isolates on transgenic poplar to understand how fungal growth and enzyme secretion adapt to variable lignin composition. Notably, no significant reductions in growth were observed highlighting the ability of anaerobic fungi to degrade diverse feedstocks regardless of lignin composition. I have additionally included preliminary work intended to identify what epigenetic regulational strategies exist for anaerobic fungi, and how they relate to carbohydrate active enzyme expression. We hope to leverage this knowledge to engineer base enzyme cocktails that release significant portions of the fermentable sugars in untreated or mildly treated plant biomass as a means to make bioenergy technologies more efficient.</p>
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Transcriptomic and metatranscriptomic approaches to characterizing genes coding for fiber digestion within the rumen ecosystemWang, Pan January 2013 (has links)
The rumen microbiome constitutes a unique genetic resource of plant fiber degrading microbial enzymes that could be used for agricultural and industrial purposes. Anaeromyces mucronatus is a poorly characterized anaerobic lignocellulolytic fungus in the rumen. This thesis aimed at better understanding A. mucronatus YE505 and the particle associated rumen microbiota based on transcriptomic and metatranscriptomic approaches. High quality RNA was isolated from the fiber-associated rumen sample based on an improved RNA extraction method. A transcriptomic study was performed to investigate the expression of the fiber degrading system of A. mucronatus YE505, and the functional diversity of the fiber-associated eukaryotes from the rumen of muskoxen (Ovibos moschatus) was explored by a metatranscriptomic study. Much carbohydrate degradation related protein modules were detected. This study established effective approaches to characterizing the functional contents of rumen eukaryotic microbiome as well as rumen fungi, and identified several candidate genes that merit further investigation. / xiv leaves : ill. (some col.) ; 29 cm
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Production of cellulolytic enzymes using immobilised anaerobic fungiMcCabe, Bernadette K., University of Western Sydney, Macarthur, Faculty of Business and Technology January 1998 (has links)
An investigation was made into the isolation and screening of highly cellulolytic anaerobic fungi and their production of cellulolytic enzymes using immobilised rhizomycelia. A total of 46 anaerobic fungi were isolated on cellulosic substrates from ruminant and non-ruminant herbivores. Primary screening of these isolates was performed using dye release from cellulose-azure which qualitatively detected cellulolytic activity. Twelve isolates were chosen on the basis of their maximum solubilisation rates of the labelled cellulose and then subjected to secondary screening which involved the quantification of enzyme activity. The enzyme mixtures were characterised by carboxymethylcellulase, xylanase, B-glucosidase, B-xylosidase and cellobiase assays, measured by the production of either reducing sugars, p-nitrophenol or glucose. All strains produced a number of enzymes that allowed them to hydrolyse straw and highest enzyme activity was measured in static cultures grown on 0.5% straw. A monocentric isolate, Piromyces strain KSX1 from a red kangaroo, and a cattle polycentric isolate, Orpinomyces strain 478P1, were selected for study of cellulolytic enzyme production on the basis of high fibre digestion capability and amenability toward encapsulation. The immobilised polycentric strain proved to be operationally superior to strain KSX1 as strain 478P1 did not produce any viable growth in the culture liquor. Studies into single batch cultures of free cells of strains KSX1 and 478P1 revealed that the maximum specific rate of B-glucosidase production occurred concomitantly with maximum specific growth rate suggesting that the immobilised fungus must grow for continuous enzyme production to occur. Although the physiology of cellulase synthesis in strains KSX1 and 478P1 was found to be growth-associated, immobilisation of the fungus offered the advantage of the repeat-batch use of cells with the accumulation of extracellular enzymes after each batch. Thus, operational gains were the key issues in assessing the potential application of immobilised anaerobic fungi in the production of cellulolytic enzymes. The repeat-batch system was operationally more efficient than the free cell batch cultures because immobilisation removed the need of reculturing the cells for every single batch. / Doctor of Philosophy (PhD)
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REFERENCE GENOMES AND GENETIC TOOLS FOR ANAEROBIC FUNGICasey A. Hooker (5930663) 07 December 2022 (has links)
<p> Non-model microorganisms offer a wealth of biotechnological potential that may be leveraged to address a variety of global grand challenges. These include challenges in carrying out complex or altogether new chemistries, discovery and production of bioactive molecules, sustainable production of biochemicals and bioproducts from renewable feedstocks, and improving agricultural practices for responsible management of carbon. Specifically, using renewable plant biomass as a substrate for production of fuels and or chemicals offers a near ubiquitous supply that does not compete with food or petrochemicals. Alternatively, identifying new natural products will be essential to addressing the ever-increasing occurrence of antibiotic resistance. Non-model organisms may provide elegant solutions to many of these challenges, whether by possessing new or more efficient strategies to depolymerize lignocellulose, by encoding enzymes with increased stabilities and or specific activities, or perhaps by containing rich biosynthetic capabilities for production of previously unidentified natural products, among others. Yet efforts to leverage non-model microorganisms for their diverse biotechnological potential remain limited to a variety of often difficult, yet not insurmountable challenges.</p>
<p> In this work, I propose anaerobic gut fungi (Neocallimastigomycota) as a robust microbial system that may be leveraged to efficiently depolymerize crude lignocellulose, increase animal nutrition, or identify novel natural products. To this end, I detail the first chromosomally resolved genome assembly of anaerobic fungi (<em>Piromyces communis </em>var. <em>indianae</em> UH3-1). I investigate the genome organization of this isolate and describe how acquisition of Carbohydrate Active EnZymes (CAZymes) contribute to the robust lignocellulolytic activity of gut fungi. I then detail efforts to build a nascent genetic engineering toolbox for these anaerobic organisms. With the acquisition of the first chromosomally resolved genome assemblies, I identify a basic set of genetic parts needed for a genetic engineering toolkit. I show these parts are functional and detail methods to enable higher throughput testing in vivo. I subsequently detail efforts to construct the first preliminary CRISPR tools for anaerobic fungi as these will be essential to establish precise DNA targeting in future strain engineering efforts. I then describe the role of epigenetics in anaerobic fungi, detailing the extent to which it may be leveraged to control gene expression. Finally, I provide a discussion of this work and describe how it may guide future efforts to domesticate these organisms. Collectively, this work provides the first chromosomally resolved genome assembly as a resource for the community, along with genetic tools and techniques to begin domesticating these non-model organisms. Importantly, this work reveals that despite the challenges associated with anaerobic microbes of relatively high complexity, they are not insurmountable, and thus efforts to domesticate them are feasible.</p>
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Aerobic Uptake of Cholesterol by Ergosterol Auxotrophic Strains in Candida glabrata & Random and Site-Directed Mutagenesis of ERG25 in Saccharomyces cerevisiaeWhybrew, Jennafer Marie 27 September 2012 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Candida albicans and Candida glabrata are opportunistic human pathogens that are the leading cause of fungal infections, which are increasingly becoming the leading cause of sepsis in immunosuppressed individuals. C. glabrata in particular has become a significant concern due to the increase in clinical isolates that demonstrate resistance to triazole antifungal drugs, the most prevalent treatment for such infections. Triazole drugs target the ERG11 gene product and prevent C-14 demethylation of the first sterol intermediate, lanosterol, preventing the production of the pathways end product ergosterol. Ergosterol is required by yeast for cell membrane fluidity and cell signaling. Furthermore, C. glabrata, and not C. albicans, has been reported to utilize cholesterol as a supplement for growth.
Although drug resistance is known to be caused by an increase in expression of drug efflux pumps, we hypothesize a second mechanism: that the overuse of triazole drugs has lead to the increase of resistance by C. glabrata through a 2-step process: 1) the accumulation of ergosterol auxotrophic mutations and 2) mutants able to take up exogenous cholesterol anaerobically in the body acquire a second mutation allowing uptake of cholesterol aerobically. Two groups of sterol auxotrophic C. glabrata clinical isolates have been reported to take up sterol aerobically but do not produce a sterol
precursor. Sterol auxotrophs have been created in C. glabrata by disrupting different essential genes (ERG1, ERG7, ERG11, ERG25, and ERG27) in the ergosterol pathway to assess which ergosterol mutants will take up sterols aerobically.
Random and site-directed mutagenesis was also completed in ERG25 of Saccharmoyces cerevisiae. The ERG25 gene encodes a sterol C-4 methyloxidase essential for sterol biosynthesis in plants, animals, and yeast. This gene functions in turn with ERG26, a sterol C-3 dehydrogenase, and ERG27, a sterol C-3 keto reductase, to remove two methyl groups at the C-4 position on the sterol A ring. In S. cerevisiae, ERG25 has four putative histidine clusters, which bind non-heme iron and a C-terminal KKXX motif, which is a Golgi to ER retrieval motif. We have conducted site-directed and random mutagenesis in the S. cerevisiae wild-type strain SCY876. Site-Directed mutagenesis focused on the four histidine clusters, the KKXX C-terminal motif and other conserved amino acids among various plant, animal, and fungal species. Random mutagenesis was completed with a procedure known as gap repair and was used in an effort to find novel changes in enzyme function outside of the parameters utilized for site-directed mutagenesis. The four putative histidine clusters are expected to be essential for gene function by acting as non-heme iron binding ligands bringing in the oxygen required for the oxidation-reduction in the C-4 demethylation reaction.
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