Bioremediation of Aquatic and Terrestrial Ecosystems

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Microbial Degradation of Hydrocarbons in the Environment. Journal of the Ghana Science Association. Guidelines for Disinfection and Sterilization in Healthcare Facilities. Fukuzaki S. Biocontrol Science, , 11 4 : Sterilization by Dry Heat. Journal of Clinical Pathology. Abeka H. Accessed Petroleum Degradation by Candida species. Environment International. Applied Microbiol. Canadian Journal of Microbiology.

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Bioremediation of Industrial Waste for Environmental Safety | gemesreiters.tk

Additional sequences were retrieved from GenBank species names followed by strains or isolates references and the corresponding accession number in brackets. As pointed out previously, dye degradation capabilities are not only species-dependent, but also strain-dependent. In twelve isolates of V. All the selected isolates were identified as basidiomycetous, which is probably a consequence of the environment from where the yeasts were isolated, decomposing leaves being rich in lignocellulosic compounds 6 , Enzymes involved in the breakdown of plant polymers or monomeric products from lignin degradation, have been associated with azo dyes degradation 11 , 15 , 16 , 19 , 23 and some of them have been previously reported as synthetized by the yeast species identified in the present work 20 , The majority of published works concerning azo dye color removal have involved mainly ascomycetous species 42 , despite some reports of using basidiomycetous yeasts 13 , 16 , 19 , 20 , Most of the basidiomycetous yeast species reported in dye decolorization are scattered in the orders Ustilaginales and Trichosporonales.

More recently Rovati et al. The present research, as in Rovati et al. In addition, two new species of Tremellales P. Other dark-colored effluents such as winery and pulp mill wastewaters were partially degraded by S. In conclusion, yeast isolates differed markedly in their ability to decolorize the tested five dyes, and the majority completely decolorized a single dye. Bioaccumulation was the preferential mechanism of color removal used for AR57 and RO The isolates with high capacity for azo dyes remediation were distributed across three Basidiomycota orders: Tremellales, Sporidiobolales and Filobasidiales.

The ability of yeasts to remove azo dyes is dependent on dye structure, species and, within species, may vary among strains. This work confirms forested wetlands as interesting, hotspots of yeasts with useful properties for treating dye-colored wastewaters, and highlights the importance of the conservation of these ecosystems, which are particularly fragile and vulnerable to variations in precipitation and temperature.

Lugo, A. Concepts in wetland ecology in Forested Wetlands. Gorham, E. Northern peatlands — role in the carbon-cycle and probable responses to climatic warming. Naiman, R. The ecology of interfaces: Riparian zones. Gallego-Fernandez, J. Small wetlands lost: a biological conservation hazard in Mediterranean landscapes. Rice, A. In vitro decomposition of Sphagnum by some microfungi resembles white rot of wood.

FEMS Microbiol. Thormann, M.

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Yeasts in peatlands: A review of richness and roles in peat decomposition. Wetlands 27 , — Fungi from peatlands. Fungal Divers. Sampaio, A. Leaf litter decomposition in western Iberian forested wetlands: lentic versus lotic response. Limnetica 27 , 93— Dynamics of yeast populations recovered from decaying leaves in a nonpolluted stream: a 2-year study on the effects of leaf litter type and decomposition time.

Ramalho, P. Improved conditions for the aerobic reductive decolourisation of azo dyes by Candida zeylanoides. Yang, Q. Decolorization of synthetic dyes and production of manganese-dependent peroxidase by new fungal isolates. Azo reductase activity of intact Saccharomyces cerevisiae cells is dependent on the Fre1p component of plasma membrane ferric reductase.

Yu, Z. Screening and identification of yeasts for decolorizing synthetic dyes in industrial wastewater. Lucas, M. Biodegradation of the diazo dye Reactive Black 5 by a wild isolate of Candida oleophila. Martorell, M. Dye-decolourizing yeasts isolated from Las Yungas rainforest. Dye assimilation and removal used as selection criteria. Tan, L. Aerobic decolorization, degradation and detoxification of azo dyes by a newly isolated salt-tolerant yeast Scheffersomyces spartinae TLHS-SF1. Song, L. Performance of a newly isolated salt-tolerant yeast strain Pichia occidentalis G1 for degrading and detoxifying azo dyes.

Pajot, H. Evidence on manganese peroxidase and tyrosinase expression during decolorization of textile industry dyes by Trichosporon akiyoshidainum.

Aquatic hyphomycetes are essential providers of ecosystem functions

Rovati, J. Yeast 30 , — Rawat, D. Detoxification of azo dyes in the context of environmental processes. Chemosphere , — Wastewater treatment systems harbor specific and diverse yeast communities. Saratale, R. Clarke, K. Plymouth Marine Laboratory, Gadanho, M.

Bioremediation of Aquatic and Terrestrial Ecosystems

Assessment of yeast diversity in a marine environment in the south of Portugal by microsatellite-primed PCR. White, T. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics in PCR protocols: a guide to methods and applications ed. Innis M. Vilgalys, R. Rapid genetic identification and mapping of enzymatically amplified ribosomal DNA from several Cryptococcus species. Reynolds, D. Thompson J. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice.


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Nucleic Acids Res. Tamura, K. Degradation of synthetic reactive azo dyes and treatment of textile wastewater by a fungi consortium reactor.

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Chengalroyen, M. Close Print this page. Content: Citation Only. Citation and Abstract. Cite this article as: Jijnasa Bordoloi and H. Related Journals. Related eBooks. Journal Insight.