Statistical Correlation between Ligninolytic Enzymes Secretion and Remazol Brilliant Yellow‐3GL Dye Degradation Potential of <i>Trametes versicolor</i> IBL‐04

Asgher, Muhammad; Shah, Syed Agha Hassan; Iqbal, Hafiz M.N.

doi:10.2175/106143016x14504669768011

Cited by 22 publications

(3 citation statements)

References 21 publications

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“…All groups showed values of F (26.60) greater than the values, indicating that there is a signi cant difference in all experiments performed in the present work. Species of Trametes are well studied for discoloration of various synthetic dyes: T. trogii discolored 7% of the remazol brilliant blue (Zouari- Mechichi et al 2006), 8% of indigo carmine (Grassi et al 2011) and 69% of Janus Green and 6% of Poly R-478 (Levin et al 2010); T. hirsuta, 94% indigo carmine, 85% of Bromophenol Blue, 41% of Methyl Orange and 47% Poly R-478 (Rodríguez- Couto et al 2006); T. membranacea, 99.2% of bromophenol blue and 71.8% of methylene blue (Lyra et al 2009); T. pubescens, 59% of Bemaplex Navy M-T and 50% of Bezaktiv Blue BA (Rodríguez-Couto et al 2014); T. versicolor, 93.5% of Remazol Brilliant Yellow 3-GL (Asgher et al 2016); and T. ljubarskyi, 97.7% of reactive violet 5 (Goh et al 2017); T. villosa, 93.8% of acid orange 142 (Ortiz-Monsalve et al 2019); T. polyzona, 90% at 100 mg L-1, 91% at 150mg L-1 and 93% at 200 mg L-1 of indigo carmine (and Uribe-Arizmendi et al 2020). However, T. lactinea has not been tested before for discoloration of dyes, while T. villosa has not been tested for discoloration of indigo carmine.Also, studies of discoloration of this dye using species, not only of Trametes, collected in Brazil are scarce.…”

Section: Discoloration Of Indigo Carminementioning

confidence: 99%

Discoloration of dyes by Trametes spp

VFdSC

et al. 2021

Preprint

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The dyes used in the textile industry contribute significantly to pollution of water sources as they are disposed, most of the time, without proper treatment. The objective of this work was to test three strains of two species of the genus Trametes collected in Brazil against the ability to discolor the indigo carmine dye and to detect the activity of the enzymes laccase, lignin peroxidase and manganese peroxidase. The experiment was carried out in Kirk medium under static, non-sterile condition, at ±28 °C for 120 h. Trametes lactinea (URM8350) discolored 81.40% of the indigo carmine dye, T. lactinea (URM8354) 85.09% and T. villosa (URM8022) 96.11%. Laccase was detected in all specimens. Manganese peroxidase was detected in T. villosa (URM8022) and T. lactinea (URM8354), while lignin peroxidase was not detected in any of the isolates under the conditions of the experiment. The discoloration rates observed demonstrate the ability of the strains to discolor carmine indigo and the promising use in the discoloration processes in wastewater from the textile segment.

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Section: Discoloration Of Indigo Carminementioning

confidence: 99%

Discoloration of dyes by Trametes spp

VFdSC

et al. 2021

Preprint

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“…In addition, recently the crude MnP enzyme extracted from I. lacteus F17 used for the degradation and detoxification of malachite green dye, which is reported as carcinogenic and mutagenic in nature [38]. In addition, various authors have reported that ligninolytic enzyme has great potential in many biotechnological applications, but unfortunately its lower catalytic efficiencies and its working stabilities limit their practical and versatile applications in many areas of the current industrial use [127][128][129][130][131][132][133][134][135].…”

Section: Miscellaneous and Emerging Applicationsmentioning

confidence: 99%

Microbial manganese peroxidase: a ligninolytic enzyme and its ample opportunities in research

et al. 2018

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Microbial ligninolytic enzymes like laccase, manganese peroxidase, and lignin peroxidase have gained much attention in many industrial applications. Among these, manganese peroxidases are key contributors in the microbial ligninolytic system. It mainly oxidizes Mn(II) ions that remain present in wood and soils, into more reactive Mn 3+ form, stabilized by fungal chelators like oxalic acids. However, Mn 3+ acts as a diffusible redox intermediate, a low molecular weight compound, which breaks phenolic lignin and produces free radicals that have a tendency to disintegrate involuntarily. It has a great application potential and ample opportunities in diverse area, such as alcohol, pulp and paper, biofuel, agriculture, cosmetic, textile, and food industries. This review article is focused on the sources, catalytic reaction mechanisms and different biotechnological applications. However, manganese peroxidases have a potential for degradation of many xenobiotic compounds and produce polymeric products formulated them into valuable tools for bioremediation purposes. In addition, microbial MnPs can also convert lignin into biomass so that the sugar can be converted into bio-fuels. Thus, this review article is mainly focused and highlighted the current scenario and updated information on manganese peroxidase enzyme.

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“…Biological treatment methods are eco-friendly, have been proven to be efficient and more cost-effective and hence are gaining importance in today's situation. Microorganisms such as actinomycetes, fungi, algae, yeast, aerobic and anaerobic bacteria and their enzymes have been successfully utilized to degrade a wide variety of dyes (Kaushik and Malik, 2009;Gupta et al, 2010;Srinivasan et al, 2014;Asgher et al, 2016). But the use of bacteria in the biological treatment of wastewater may result in the generation of colorless, dead-end aromatic amine which is generally more hazardous than the parent compounds and thus may have poor usage and limited application in the treatment of dye effluents (Guaratini et al, 2001;Hadibarata et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Biotransformation and detoxification of reactive black dye by Ganoderma tsugae

Zubbair¹,

Ajao²,

Adeyemo³

et al. 2018

Afr. J. Environ. Sci. Technol.

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In this study, the decolourization potential of the white-rot fungus Ganoderma tsugae, which is capable of producing laccase was investigated to degrade reactive black dye. Biodegradation of reactive black dye was analyzed by using spectrophotometer at an absorbance of 585 nm. Laccase, manganese peroxidase and pH were served as biodegradation indices. Fourier transform infrared (FTIR) and gas chromatography mass spectrometry (GCMS) were used to analyze degradation products. Seed germination study was carried out on maize and beans seeds with distilled water (control), degraded dye products and non-degraded dye. Microtoxicity assay was also performed on the test cultures Escherichia coli, Pseudomonas aeruginosa and Klebsiella pneumoniae using the degraded dye metabolite/non-degraded dye. The non-degraded dye components inhibited the growth of P. aeruginosa (clear zone of 6 mm) and E. coli (clear zone of 3 mm). K. pneumoniae was resistant to the toxicity of the dye components. The following metabolites were detected; 3-Benzyl hexahydropyrrolo[1,2-a]pyrazine-1,4-dione, 5-Isopropylidene-3,3-dimethyl-dihydrofuran-2-one, N-[(Z)-1-Ethylpentylidene] methanamine and 10-Undecenyl aldehyde with retention time of 23.317, 16.475, 16.850 and 23.500 min, respectively.

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Statistical Correlation between Ligninolytic Enzymes Secretion and Remazol Brilliant Yellow‐3GL Dye Degradation Potential of Trametes versicolor IBL‐04

Cited by 22 publications

References 21 publications

Discoloration of dyes by Trametes spp

Discoloration of dyes by Trametes spp

Microbial manganese peroxidase: a ligninolytic enzyme and its ample opportunities in research

Biotransformation and detoxification of reactive black dye by Ganoderma tsugae

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