The utilization of lignocellulosic wastes for laccase production under semisolid-state and submerged fermentation conditions

Birhanlı, Emre; Yeşilada, Özfer

doi:10.3906/biy-1211-25

Cited by 36 publications

(29 citation statements)

References 35 publications

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“…In trying to answer questions surrounding the emergence of antibiotic resistance and the need for new antimicrobials, Büttel et al. () posed the question, “ Can we, by unlocking the hidden potential of fungi, attain new means to gain advantage of this battle ?” As much as this question could have been focused on antibiotics, fungi are a source of many other biotechnologically important molecules ranging from enzymes (Birhanli & Yeşilada, ; Elisashvili et al., ) to medicinal and therapeutic molecules (Gupta, Saxena, & Goyal, ; Hong et al., ). Whole cell or culture forms of fungi have also been applied to the bioremediation of metal‐polluted environments (Iram, Zaman, Iqbal, & Shabbir, ; Kumar, Singh, Dhir, Sharma, & Mehta, ; Siddiquee, Aishah, Azad, Shafawati, & Naher, ), biotreatment of raw wastewater (Coulibaly, Gourene, & Agathos, ; Novotny et al., ), and the bioremediation of persistent pollutants like plastics (Manzur & Limo, ), organochlorides (Tekere, Ncube, Read, & Zvauya, ) and petroleum hydrocarbons (Makut, Ogbonna, Ogbonna, & Owuna, ; Zafra, Absalón, & Cortés‐Espinosa, ).…”

Section: Introductionmentioning

confidence: 99%

Potential biotechnological capabilities of cultivable mycobiota from carwash effluents

Sibanda¹,

Selvarajan²,

Tekere³

et al. 2017

MicrobiologyOpen

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Urban life has created man‐made extreme environments like carwashes. These environments have, however, not been sufficiently explored for mycobiota that can be sources of biotechnologically useful products, as has been the case with natural extreme environments. Using a combination of culture and molecular techniques, fungi from carwash effluents was characterized for production of lipase and cellulase enzymes, nonpolar and polar biotechnologically relevant secondary metabolites and hydrocarbon utilization. The isolated fungal strains belonged to the genera Alternaria, Cladosporium, Penicillium, Peyronellaea, Rhizopus, Spegazzinia, Trichoderma, Ulocladium and Yarrowia. Sixty‐six percent (66%) of the fungal isolates were found to be able to metabolize naphthalene and benzanthracene, showing potential for application in bioremediation of hydrocarbon polluted sites. Lipase production by the isolates Penicillium sp. BPS3 (2.61 U/ml), Trichoderma sp. BPS9 (2.01 U/ml), Rhizopus sp. CAL1 (2.05 U/ml), Penicillium sp. PCW1 (2.99 U/ml) and Penicillium sp. SAS1 (2.16 U/ml) compared well with previously recorded lipase production levels by other fungi. The highest producers of cellulase were Penicillium sp. SAS1 (12.10 U/ml), Peyronella sp. CAW5 (4.49 U/ml) and Cladosporium sp. SAS3 (4.07 U/ml), although these activities were lower than previously reported levels. GC‐MS analysis of the fungal secondary metabolites resulted in identification of 572 compounds, including azulene, methanamine, N‐pentylidene, metoclopramide, and mepivacaine while compounds determined by UHPLC‐MS included 10‐undecen‐1‐ol, piquerol A, 10‐undecyn‐1‐ol, cyclo(leucylprolyl) and rac‐etomidate. These compounds were previously determined to have various activities including anticancer, antibacterial, antifungal, antihypertensive, antidiabetic and anti‐inflammatory properties. The study demonstrated that fungi from carwash effluents are natural sources of some biotechnologically important products.

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Section: Introductionmentioning

confidence: 99%

Potential biotechnological capabilities of cultivable mycobiota from carwash effluents

Sibanda¹,

Selvarajan²,

Tekere³

et al. 2017

MicrobiologyOpen

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“…White rot fungal species could produce several laccase isozymes. Culture conditions, fermentation mode, type and amount of nutrient, and inducers may affect the laccase production (Janusz et al, 2006;Birhanlı and Yeşilada, 2013) by influencing the expression of these isozymes (Giardina et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Reactive dye decolorization activity of crude laccase enzyme from repeated-batch culture of Funalia trogii

Yeşilada¹,

Birhanlı²,

Ercan³

et al. 2014

Turk J Biol

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The effect of various factors on dye decolorization activity of crude laccase enzyme from repeated-batch culture of Funalia trogii ATCC 200800 to obtain rapid and high decolorization activity against Reactive Black 5 and Reactive Blue 171 dyes was investigated. All conditions used were important for dye decolorizing activity of this crude laccase enzyme. The optimum pH of decolorization was tested at 30 °C and it was around 3.0. This activity was highly reduced at pH 4.5-6.0. On the other hand, the optimum temperature for rapid and high decolorization was 50 °C. Importantly, the decolorization rate of crude laccase at pH 4.5 and pH 6.0 increased with the rise in temperature from 30 °C to 50 °C. Therefore, high decolorization could be obtained at pH 4.5 and even pH 6.0 by selecting the proper temperature for these pH values. Enzyme amount also affected the dye decolorization positively. This crude laccase could also decolorize the mixed dyes (Reactive Black 5 and Reactive Blue 171) and synthetic wastewaters. Native polyacrylamide gel electrophoresis showed the responsibility of the laccase enzyme in decolorization. Rapid and high textile dye decolorization through the selection of appropriate conditions could facilitate the development of more economical and environmentally friendly processes.

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“…The reaction mixture contained 833 µL of sodium acetate buffer (100 mM, pH 5.0), 100 µL of ABTS (0.5 mM), and a suitable amount of crude laccase enzyme. One unit of laccase activity was defined as the amount of enzyme that oxidized 1 µmol of ABTS per min at 30 °C (Murugesan et al, 2007;Birhanlı and Yeşilada, 2013 Figure 1A). In addition to SDS-PAGE, native PAGE was also performed under nondenaturating conditions.…”

Section: Laccase Activity Assaymentioning

confidence: 99%

“…In the present work, Trametes versicolor (T. versicolor) ATCC 200801 was chosen as an excellent laccase-producing white rot fungus according to our previous studies (Birhanli and Yesilada, 2006;Boran and Yesilada, 2011;Birhanlı and Yeşilada, 2013). Since fungal pellets can be used repeatedly for high amounts of laccase production, the repeated-batch method was used as the fermentation process.…”

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confidence: 99%

The effect of various inducers and their combinations with copper on laccaseproduction of Trametes versicolor pellets in a repeated-batch process

Birhanlı¹,

Yeşilada²

2017

Turk J Biol

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Introduction Laccases(EC 1.10.3.2, p-diphenol:dioxygen oxidoreductases) are industrially important multicoppercontaining enzymes. Although laccases are produced by some higher plants, insects, bacteria, and fungi, these enzymes are mainly abundant in white rot fungi (Gochev and Krastanov, 2007;Shraddha et al., 2011). These fungi, including Trametes, Pleurotus, Coriolopsis, and other genera, produce laccase enzymes at varying rates (Tapia-Tussell et al., 2011). Trametes is one of the most effective laccase-producing genera (Jang et al., 2002;Rosales et al., 2007). Fungal laccases are generally extracellular and they catalyze the oxidation of a wide range of compounds, such as mono-, di-, and polyphenols, aminophenols, methoxyphenols, aromatic amines, ascorbate, and nonphenolic compounds (Thurston, 1994;Couto et al., 2002;Baldrian, 2006;Patel and Gupte, 2016). The nonnecessity of any extraction process for obtaining these enzymes and their low substrate specificities make laccases suitable for many industrial applications, such as pulp delignification and biobleaching, textile dye decolorization, wastewater treatment, fruit juice processing, and construction of biosensors and biofuel cells (Minussi et al., 2002;Giardina et al., 2010;Durán et al., 2014;Yeşilada et al., 2014). Due to their broad industrial and environmental uses, these enzymes have gained increasing attention. Laccase production can be stimulated by various inductive substances, including metal ions, aromatic or phenolic compounds, alcohol, and detergents (Collins and Dobson, 1997;Birhanli and Yesilada, 2006;Tychanowicz et al., 2006;Bettin et al., 2014). Furthermore, inducer concentration, fermentation types, growth media, and incubation conditions have an important effect on laccase production and they are specific to species and strains (Boran and Yesilada, 2011). Many researchers have investigated the effects of various fermentation processes, cultivation conditions, laccase-producing organisms, and inducers on laccase production (

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The utilization of lignocellulosic wastes for laccase production under semisolid-state and submerged fermentation conditions

Cited by 36 publications

References 35 publications

Potential biotechnological capabilities of cultivable mycobiota from carwash effluents

Potential biotechnological capabilities of cultivable mycobiota from carwash effluents

Reactive dye decolorization activity of crude laccase enzyme from repeated-batch culture of Funalia trogii

The effect of various inducers and their combinations with copper on laccaseproduction of Trametes versicolor pellets in a repeated-batch process

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