Bioremediation treatments for polyaromatic hydrocarbons contaminated soil

Riaz, Ihsan

January 2002

No description available.

628

White rot fungi

Application of White-rot Fungi for the Biodegradation of Natural Organic Matter in Wastes

Lee, Monn Kwang, monnlee@hotmail.com

January 2006

Natural organic matter (NOM), a complex mixture of organic compounds, influences drinking water quality and water treatment processes. The presence of NOM is unaesthetic in terms of colour, taste and odour, and may lead to the production of potentially carcinogenic disinfection by-products (DBPs), as well as biofilm formation in drinking water distribution systems. Some NOM removal processes such as coagulation, magnetic ion exchange resin (MIEXTM) and membrane filtration produce sludge and residuals. These concentrated NOM-containing sludges from alum precipitation, membrane treatment plants and MIEX regeneration must therefore be treated prior to disposal. The white-rot fungi possess a non-specific extracellular oxidative enzyme system composed of lignin peroxidase (LiP), manganese-dependent peroxidase (MnP) and laccase (Lac) that allows these organisms to mineralise lignin and a broad range of intractable aromatic xenobiotics. Rojek (2003) has shown the capabi lity of Phanerochaete chrysosporium ATCC 34541 to remove 40-50% NOM from solution, however, this was found to be mainly due to adsorption and to be a partially metabolically linked activity. Consequently, the bioremediation of NOM wastes by selected white-rot fungi was further investigated in the present study. The P. chrysosporium seemed to preferentially remove the very hydrophobic acid (VHA) fraction, and so was most effective for a NOM preparation with a high proportion of hydrophobic content (and so high in colour and specific UV absorbance (SUVA)). The extent of NOM decolourisation by P. chrysosporium in three growth media with different C:N ratios followed the trends: Waksman (C:N = 6) > Fahy (C:N = 76) > Fujita medium (C:N = 114), such that the lower the C:N ratio, the greater NOM removal. This was consistent with the findings of Rojek (2003), who used a different NOM preparation and demonstrated that the removal of NOM increased with decreased C:N ratio (1.58-15.81). As removals of NOM with P. c hrysosporium ATCC 34541 were low, and little biodegradation occurred, this organism was compared with P. chrysosporium strain ATCC 24725, Trametes versicolor ATCC 7731, and three strains of yeast (Saccharomyces species arbitrarily denoted 1, 2 and 3). T. versicolor gave the greatest removal (59%) which was attributed largely to degradation, whereas the NOM removal by the two strains of P. chrysosporium (37%) and the yeast was predominantly due to adsorption as indicated by the deep brown colouration of the biomass. Saccharomyces sp. 1, 2 and 3 removed 12%, 61% and 23% of the colour, respectively. Although Saccharomyces sp. 2 had similar high colour reduction to T. versicolor, the specific removal values differed markedly: 0.055 compared to 0.089 mg NOM/mg biomass, respectively. The low level of the ligninolytic enzymes secreted by both strains of P. chrysosporium corresponded with the low degree of NOM removal by biodegradation as shown by high performance size exclusion chromatography (HPSEC). The high NOM removal attained by T. versicolor was attributed to the activities of the ligninolytic enzymes, especially laccase. The NOM removal was attributed to the breakdown of the high molecular weight compounds to form a pool of low molecular weight materials, which were then most likely utilised by the T. versicolor. Growth of T. versicolor cultures at 36oC caused inhibition or denaturation of the activity of the phenoloxidase enzymes compared to those grown at 30oC. The low activity of LiP in both cultures suggested that this enzyme may not play much of a role in NOM removal. The higher levels of MnP and Lac activities at 30oC were responsible for the greater NOM removal (73% vs. 59%) and thus the cleavage of aromatic rings, conjugated and C-Cβ αbonds in phenolic moieties, as well as catalysing alkyl-aryl cleavage in the NOM structures. T. versicolor cultured in Waksman medium with higher initial glucose (5 g/L cf. 2 g/L) led to lower ligninolytic enzyme activities and a lower degree of NOM removal (25% less colour reduction), probably due to preferential use of glucose over NOM as carbon source. NOM removal (mg removed) increased linearly with NOM concentration up to 600 mg C/L (62 mg (A446); 31 mg (A254)), above which removal decreased markedly. This trend coincided with increasing total ligninolytic enzyme activity, where the level of Lac increased up to 600 mg C/L NOM although MnP decreased gradually across the range while LiP was only detected for 100 and 300 mg C/L NOM. Hence, the removal of NOM from solution by T. versicolor was associated with high oxidative enzyme activity, particularly of laccase. Laccase was the major extracellular enzyme secreted by T. versicolor and by deduction, played a major role in NOM removal. The optimum temperature for Lac activity secreted by T. versicolor cultured in Waksman medium supplemented with 4.5 g/L wheat bran plus 0.5% Tween 80 was determined to be 50oC. The optimum pH for the Lac activity for guaiacol and NOM was identified as pH 4.0-4.5. Although the optimum enzyme activity occurred at 50oC, 30oC was recommended for enzymatic removal of NOM as the phenoloxidase enzyme activity may be denatured if the NOM removal process were considered to run for long period at high temperature. Although agitation led to apparent enzyme denaturation, fermentations with continuous agitation promoted enzyme activity faster than those with occasional agitation (agitated every 6 hours for 30 minutes at 130 rpm and 30oC) as it provides better mass transfer. However, it seemed that continuous agitation had an adverse effect on the fungal growth and enzyme production over extended fermentation periods. Addition of 4.5 g/L wheat bran to modified Waksman medium in the absence of NOM led to high production of Lac activity compared with LiP and MnP activities, showing its great potential as a laccase inducer. Addition of Tween 80 alone to the cultures led to a small improvement in Lac activity; however, with the presence of wheat bran it caused marked increases in LiP, MnP and Lac activit ies. When NOM was added to cultures of T. versicolor with the two supplements, it led to markedly reduced Lac activity, but increased LiP and MnP activities, and no improvement in NOM removal compared with the cultures in the absence of supplements (12 mg (or 61%) cf. 15 mg (or 73%) for 100 mg C/L after corrected for colour from and adsorption by wheat bran).

biodegradation

natural organic matter

white-rot fungi

Decolorisation of phenolic industrial wastes using Trametes versicolor

Summerwill, Michah

January 1994

No description available.

628.168

Bioaugmentation using Pleurotus ostreatus to Remediate Polycyclic Aromatic Hydrocarbons (PAH) Contaminated River Sediment

Bosiljcic, Gregory Roy

12 September 2008

No description available.

Biology

Environmental Science

Microbiology

Remediation

White rot fungi

PAH

Introduction and utilization of a gene targeting system in a basidiomycete Pleurotus ostreatus using CRISPR/Cas9 genome editing technology / 担子菌ヒラタケへのCRISPR/Cas9ゲノム編集技術を用いた遺伝子ターゲティング系の導入と利用

BOONTAWON, TATPONG

24 September 2021

京都大学 / 新制・課程博士 / 博士(農学) / 甲第23521号 / 農博第2468号 / 新制||農||1087(附属図書館) / 学位論文||R3||N5352(農学部図書室) / 京都大学大学院農学研究科地域環境科学専攻 / (主査)教授 本田 与一, 教授 田中 千尋, 准教授 坂本 正弘 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

basidiomycete

white-rot fungi

CRISPR/Cas9

dikaryozation

gene targeting

610

Degradation of PCP by laccases of the white-rot fungus Trametes sp. HR577 : a thesis presented in partial fulfilment of the degree of Doctor of Philosophy in Chemistry at Massey University, Palmerston North, New Zealand

Guthrie, Jenness Margaret

Unknown Date

Pentachlorophenol (PCP) is a biocide used by the NZ forestry industry until 1988. Its use was discontinued due to its toxicity to humans and animals. White-rot fungi have been shown to degrade PCP in laboratory and field trials. New Zealand native white-rot fungi were screened to identify organisms suitable for the clean up of PCP contaminated sites. Four criteria were used for the screening: fungal growth at different temperatures, PCP and creosote resistance and PCP degradation in standard liquid medium. Twenty isolates were identified as potentially useful from over 200 that were screened. One unique isolate, Trametes sp. HR577, was chosen for intensive study because it produced the well known laccases previously described from other PCP-degrading white-rot fungi. The white-rot isolate HR577 was assigned to the genus Trametes based on morphological characteristics and gene sequencing studies. The latter showed that the partial laccase gene sequences from Trametes sp. HR 577 had high sequence homology to laccases from other Trametes species, especially T. versicolor and T. villosa. Two laccase isozymes, designated L1c and L2, were purified from Trametes sp. HR577. These isozymes had similar biological properties to other Trametes species laccase isozymes. Both isozymes had a relatively high temperature optima, however, they were not very stable at elevated temperature. The dependence of laccase on dissolved oxygen for catalysis was demonstrated for isozyme L2. Laccase activity was severely inhibited in the absence of dissolved oxygen. This could be restored by reoxygenation into the assay system. Whole cultures of Trametes sp. HR577 grown in liquid culture removed up to 76% of PCP after 72 hours. PCP removal was mostly due to degradation rather than adsorption of PCP to fungal mycelium. Addition of purified and crude laccase isozymes (100 U mL-1) did not enhance PCP degradation. 6-15% of PCP was removed from solutions containing solely purified isozyme L1c or L2 in acetate buffer over 72 hours. Addition of ethanol or the laccase mediator compound 2,2' azinobis(3-ethylbenzthiazoline-6-sulfonic acid) (ABTS) resulted in increased PCP disappearance from purified laccase cultures. These studies show that the white-rot Trametes sp. HR577 has potential to be used for the clean up of PCP contaminated sites in NZ.

pentachlorophenol

white-rot fungi

site remediation

Elimination des perturbateurs endocriniens nonylphénol, bisphénol A et triclosan par l'action oxydative de la laccase de coriolopsis polyzona

Cabana, Hubert

04 April 2008

Les substances perturbatrices du système endocrinien sont des substances qui, de par leur capacité à induire des changements hormonaux chez les organismes vivants, génèrent des préoccupations dans le domaine de la qualité des eaux et, par extension, dans le domaine du traitement des effluents aqueux. Particulièrement, ce projet de recherche s’est attardé sur l’élimination des perturbateurs endocriniens phénoliques nonylphénol (NP), bisphénol A (BPA) et triclosan (TCS) en solution aqueuse à l’aide de la laccase (E.C. 1.10.3.2) sécrétée par la souche fongique Coriolopsis polyzona. Cette oxydase est une métalloprotéine pouvant catalyser l’oxydation d’une vaste gamme de substances phénoliques. En premier lieu, l’impact du pH et de la température sur l’élimination de ces composés à l’aide de la laccase libre en utilisant un design factoriel. L’oxydation de ces composés produit des oligomères (dimère à pentamère) via le couplage des radicaux phénoxy produits par l’action de la laccase. Il s’avère que les substances produites suite à l’oxydation du NP et du BPA par la laccase ont perdu leurs similitudes structurales avec l’estrogène. Ainsi, l’élimination de l’activité estrogénique de ces substances est directement liée à la transformation des composés. Finalement, l’utilisation d’ABTS comme médiateur a permis d’augmenter le taux d’oxydation enzymatique de ces composés chimiques. Puis, de façon à augmenter la possibilité d’utilisation de la laccase dans des biotechnologies environnementales, cette enzyme a été immobilisée sur un support siliceux et via la réticulation d’agrégats. L’impact des conditions d’immobilisation sur l’activité enzymatique, la stabilité du catalyseur et les propriété biocatalytiques apparentes a été déterminé pour différentes stratégies d’immobilisation. Globalement, l’immobilisation génère un biocatalyseur stable vis-à-vis les dénaturations chimique, physique et biologique. Particulièrement, l’immobilisation sur un support solide produit un biocatalyseur facile à utiliser ayant une faible activité massique et des propriétés cinétiques moindres que celle de l’enzyme libre. La formation de CLEAs de laccase a permis d’obtenir une activité massique élevée et des propriétés cinétiques supérieures à celle de l’enzyme soluble. Ces biocatalyseurs solides ont étés utilisés pour éliminer en continu le NP, BPA et TCS dans différents types de bioréacteur. Le biocatalyseur sur silice a été utilisé pour éliminer ces substances dans un réacteur garni, tandis que les CLEAs ont été utilisés dans un réacteur à lit fluidisé et un réacteur à perfusion développé au cours de ce projet. Ces différentes configurations de bioréacteur ont permis d’éliminer efficacement ces différents perturbateurs endocriniens. Globalement, les différents résultats obtenus, à l’échelle de laboratoire, au cours de ce projet de recherche démontrent que la laccase et particulièrement les biocatalyseurs formés via les différentes stratégies d’immobilisation testées représentent des approches extrêmement prometteuses pour le développement de biotechnologies environnementales vouées à l’élimination des perturbateurs endocriniens phénoliques.

Endocrine disrupting chemical

Oligomerization

Immobilization

White rot fungi

Laccase

Triclosan

Nonylphenol

Bisphenol A

Characterization of Pleurotus ostreatus mutants defective in lignin degradation using reverse genetic and comparative transcriptomic analyses / 逆遺伝学および比較トランスクリプトーム解析を用いたヒラタケリグニン分解不全変異株の特性評価

WU, HONGLI

24 November 2020

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第22854号 / 農博第2437号 / 新制||農||1082(附属図書館) / 学位論文||R2||N5314(農学部図書室) / 京都大学大学院農学研究科地域環境科学専攻 / (主査)教授 本田 与一, 教授 田中 千尋, 准教授 坂本 正弘 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM

basidiomycete

white-rot fungi

transcriptome

genetic analysis

gene targeting

histon modification

lignocellulose

610

Regulation Of Selective Delignification In The White-Rot Decay Fungus Phanerochaete Chrysosporium

Parker, Leslie Anne

09 December 2011

To gain a better understanding of the mechanisms by which the white-rot decay fungus Phanerochaete chrysosporium regulates selective delignification versus simultaneous decay, differential gene expression of its two key enzymes were measured over the course of aspen and birch wood decay tests. The type of decay was determined by differential staining and scanning electron microscopy. Real-time qPCR assessed gene expression of four lignin peroxidase genes and two manganese peroxidase genes at each stage of decay. Differential expression was significant in the mnp2 gene between aspen and birch decay tests during incipient decay; abundant expression of mnp2 in aspen corresponded to early initiation of selective delignification, whereas birch underwent initial simultaneous decay in the absence of abundant mnp2 expression. The lipC gene was the most abundantly expressed lip gene at all time points in both wood species and likely plays an important role in regulating wood decay.

selective delignification

regulation

manganese peroxidase

lignin peroxidase

white-rot fungi

gene expression

Phanerochaete chrysosporium

Effect of Pleurotus ostreatus on Bioremediation of PAH Contaminated River Sediment

Gacura, Matthew David

01 October 2009

No description available.

Microbiology

Bioremediation

PAHs

White rot fungi

Pleurotus ostreatus

Aerobic degradation

Polycyclic aromatic hydrocarbons