Improvement Strategies, Cost Effective Production, and Potential Applications of Fungal Glucose Oxidase (GOD): Current Updates

Dubey, Manish Kumar; Zehra, Andleeb; Aamir, Mohd; Meena, Mukesh; Ahirwal, Laxmi; Singh, Swati; Shukla̽, Shruti; Upadhyay, Ram Sanmukh; Bueno-Marí, Rubén; Bajpai, Vivek K.

doi:10.3389/fmicb.2017.01032

Cited by 85 publications

(57 citation statements)

References 272 publications

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“…It is a dimeric protein consisting of two identical 80 kDa subunits that contain non-covalently bound flavin adenine dinucleotide (FAD) per monomer as cofactor at the active site 3 . Glucose oxidase is widely employed in food industry due to its ability to remove glucose and oxygen (O 2 ) or to produce glu-conic acid 4 . It is also used in chemical, pharmaceutical, textile, and other biotechnological industries.…”

Section: Introductionmentioning

confidence: 99%

Immobilization of Glucose Oxidase on Eupergit C: Impact of Aeration, Kinetic and Operational Stability Studies of Free and Immobilized Enzyme

Pečar¹

2019

Chem.Biochem.Eng.Q.

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The effect of aeration on the stability of glucose oxidase in the reaction of glucose oxidation to gluconic acid was investigated by determining the operational stability decay rate constant in the process conditions. Eupergit C as a porous carrier was chosen for the enzyme immobilization. To evaluate glucose oxidase operational stability during process conditions, experiments of glucose oxidation were carried out in the repetitive batch reactor with and without continuous aeration at different aeration levels. It was found that the decay rate of the free enzyme linearly depended on the air flow rate. Immobilization of glucose oxidase on Eupergit C significantly enhanced enzyme stability at higher aeration rates. Kinetics of the free and immobilized enzyme was also determined. The mathematical model of glucose oxidation catalysed by free and immobilized glucose oxidase in the batch reactor was developed.

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Section: Introductionmentioning

confidence: 99%

Immobilization of Glucose Oxidase on Eupergit C: Impact of Aeration, Kinetic and Operational Stability Studies of Free and Immobilized Enzyme

Pečar¹

2019

Chem.Biochem.Eng.Q.

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“…The three enzymes studied in this work have applications in several industries: GOD in food, beverage, and textile industries, and in glucose biosensors (Bankar et al, 2009 ; Dubey et al, 2017 ); Inv in the production of invert sugars and prebiotic compounds (Kulshrestha et al, 2013 ; Kadowaki et al, 2014 ; Nadeem et al, 2015 ); and ALP in diagnostic studies, in biosensors and as a marker for milk pasteurization (Rankin et al, 2010 ; Nalini et al, 2015 ). To the best of our knowledge, there are not many studies (or even none) regarding the secretion of GOD, Inv, and ALP enzymes in yeasts, especially from yeasts inhabiting cold environments.…”

Section: Discussionmentioning

confidence: 99%

“…GOD (β-D-glucose:oxygen 1-oxidoreductase; EC 1.1.2.3.4) catalyzes the oxidation of β-D-glucose to gluconic acid, also producing hydrogen peroxide, by using molecular oxygen as an electron acceptor (Bankar et al, 2009 ). This enzyme is applied in the food, beverage, chemical, pharmaceutical, and biotechnological industries (Ferri et al, 2011 ; Du et al, 2013 ; Dubey et al, 2017 ), and has novel applications in biosensors (Bankar et al, 2009 ; Wang et al, 2013 ). Due to this potential, the search for GODs from microbial sources is increasing.…”

Section: Introductionmentioning

confidence: 99%

Biochemical and Thermodynamical Characterization of Glucose Oxidase, Invertase, and Alkaline Phosphatase Secreted by Antarctic Yeasts

Yuivar

Barahona

Alcaı́no

et al. 2017

Front. Mol. Biosci.

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The use of enzymes in diverse industries has increased substantially over past decades, creating a well-established and growing global market. Currently, the use of enzymes that work better at ambient or lower temperatures in order to decrease the temperatures of production processes is desirable. There is thus a continuous search for enzymes in cold environments, especially from microbial sources, with amylases, proteases, lipases and, cellulases being the most studied. Other enzymes, such as glucose oxidase (GOD), invertase (Inv), and alkaline phosphatase (ALP), also have a high potential for application, but have been much less studied in microorganisms living in cold-environments. In this work, secretion of these three enzymes by Antarctic yeast species was analyzed, and five, three, and five species were found to produce extracellular GOD, Inv, and ALP, respectively. The major producers of GOD, Inv, and ALP were Goffeauzyma gastrica, Wickerhamomyces anomalus, and Dioszegia sp., respectively, from which the enzymes were purified and characterized. Contrary to what was expected, the highest GOD and Inv activities were found at 64°C and 60°C, respectively, and at 47°C for ALP. However, the three enzymes maintained a significant percentage of activity at lower temperatures, especially ALP that kept a 67 and 43% of activity at 10°C and 4°C, respectively.

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“…P2O is a flavoenzyme oxidase that catalyzes the selective oxidation of the C−H bond which contains an ‐OH group in the sugar to generate a corresponding keto‐sugar product. The enzyme belongs to the GMC enzyme family which also catalyzes oxidation of the C−H bond in other substrates . P2O is among the most useful sugar‐specific biocatalysts for industrial applications because it can catalyze regiospecific oxidative transformation of aldoses into 2‐keto‐aldoses, which are precursors for the synthesis of valuable compounds such as fructose, tagatose, isoascorbic acid or the antibiotic cortalcerone .…”

Section: Introductionmentioning

confidence: 99%

The Mechanism of Sugar C−H Bond Oxidation by a Flavoprotein Oxidase Occurs by a Hydride Transfer Before Proton Abstraction

Wongnate

Surawatanawong

Chuaboon

et al. 2019

Chemistry A European J

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Understanding the reaction mechanism underlying the functionalization of C−H bonds by an enzymatic process is one of the most challenging issues in catalysis. Here, combined approaches using density functional theory (DFT) analysis and transient kinetics were employed to investigate the reaction mechanism of C−H bond oxidation in d‐glucose, catalyzed by the enzyme pyranose 2‐oxidase (P2O). Unlike the mechanisms that have been conventionally proposed, our findings show that the first step of the C−H bond oxidation reaction is a hydride transfer from the C2 position of d‐glucose to N5 of the flavin to generate a protonated ketone sugar intermediate. The proton is then transferred from the protonated ketone intermediate to a conserved residue, His548. The results show for the first time how specific interactions around the sugar binding site promote the hydride transfer and formation of the protonated ketone intermediate. The DFT results are also consistent with experimental results including the enthalpy of activation obtained from Eyring plots, as well as the results of kinetic isotope effect and site‐directed mutagenesis studies. The mechanistic model obtained from this work may also be relevant to other reactions of various flavoenzyme oxidases that are generally used as biocatalysts in biotechnology applications.

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Improvement Strategies, Cost Effective Production, and Potential Applications of Fungal Glucose Oxidase (GOD): Current Updates

Cited by 85 publications

References 272 publications

Immobilization of Glucose Oxidase on Eupergit C: Impact of Aeration, Kinetic and Operational Stability Studies of Free and Immobilized Enzyme

Immobilization of Glucose Oxidase on Eupergit C: Impact of Aeration, Kinetic and Operational Stability Studies of Free and Immobilized Enzyme

Biochemical and Thermodynamical Characterization of Glucose Oxidase, Invertase, and Alkaline Phosphatase Secreted by Antarctic Yeasts

The Mechanism of Sugar C−H Bond Oxidation by a Flavoprotein Oxidase Occurs by a Hydride Transfer Before Proton Abstraction

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