Purification, Characterization, Crystallization And Preliminary X-ray Structure Determination Of Scytalidium Thermophilum Bifunctional Catalase And Identification Of Its Catechol Oxidase Activity

Sutay, Didem

01 June 2007

In this study, the aim was identification and classification of the enzyme having phenol oxidase activity produced by a thermophilic fungus, Scytalidium thermophilum. For this purpose, enzyme production, purification, biochemical characterization and structural analysis by X-ray crystallography studies have been performed. At the beginning of the research, this enzyme was considered as a phenol oxidase and analyzed accordingly. However, during purification, amino acid sequencing and structural studies, the enzyme was shown to be a catalase, with an additional catechol oxidase activity. This novel bifunctional catalase-catechol oxidase (CCO) was purified 10 fold with 45 % yield by anion exchange and gel filtration chromatographies. CCO was determined as a tetrameric protein having total and subunit molecular weights of 320 and 80 kDa, respectively. Isoelectric point of CCO was verified as 5.0. CCO catalase and catechol oxidase activities were characterized in terms of their kinetic behavior at different pH and temperatures. Depending on the substrate specificity and inhibitor studies of CCO, the phenol oxidase activity was determined as catechol oxidase but not tyrosinase or laccase. The best crystallization condition for CCO was determined and X-ray diffraction data was collected at the Daresbury Synchrotron Radiation Source (United Kingdom) at 2.7 &Aring / resolution. The preliminary structure was solved by molecular replacement method using Penicilium vitale catalase structure. CCO was verified to have a tetrameric structure with two homodimers and a metal center in each polypeptide chain.

TP Biotechnology 248.13-248.65

Copper and iron complexes of linear and crosslinked polymers as catalysts for phosphoester hydrolysis and oxidative transformation of phenolic and catecholic substrates

Lykourinou, Vasiliki

01 June 2006

The goal of this study is to utilize polymers as macromolecular ligands for the construction of catalysts by formation of coordination complexes with transition metals with the main focus on complexes of Cu(II) and Fe(III) and further determine (a) their catalytic efficiency (b) mechanism of action (c) similarities to enzymatic systems and synthetic metal complexes. The reactions of interest are (1) hydrolytic cleavage of a series of phosphoesters(2) oxidation of catechol type of substrates (3) hydroxylation of phenolic substrates and chlorinated phenols (4) activation of molecular oxygen and/ or hydrogen peroxide (5)oxidative cleavage of DNA plasmid. The major premise of the study is that by mimicking the macromolecular nature and some structural features of enzymes, polymers can in principle, catalyze chemical transformations with similar efficiencies and specificities and can offer alternatives to peptide based catalysts or simple metal complexes with the advantage of a wider range of building blocks, increased stability and the potential of reusability. The crosslinked resins used contained the functional groups iminodiacetate (chelex resin), diethylenetriamine and tris(2-aminomethylamine) and were based on styrene-divinylbenzene backbone. The catalytic proficiencies of the Fe(III) and the Cu(II) complexes of chelex resin and diethylenetriamine approached 100 and 1000 respectively towards the model phosphodiester BNPP at pH 8.0 and 25°C. Moreover, the Fe(III) complexes of linear copolymers with repeating unit of three vinylpyridines to one acrylamide (P1) showed selectivity towards phosphodiester hydrolysis over monoesters and phosphonate esters and exhibited catalytic proficiencies approaching 50,000 towards BNPP hydrolysis. Further exploration of the catalytic capabilities of copolymer P1 revealed that Cu(II) complexes of this macromolecular ligand are potentially capable of assembling to active dicopper intermediates found in the catalytic pathways of copper oxygenases like tyrosinase and catechol oxidase and thus were able to accelerate catechol oxidation to ortho-quinones with rate accelerations approaching 10,000 and hydroxylate phenols with rate accelerations close to one million. The results suggest that these Cu(II)-polymer systems can potentially be used as model systems to further understand metal centered reactive oxygen species (ROS) generated in vivo and can be very promising remediation agents for the dechlorination of persistant chlorine containing pollutants.

Catechol oxidase

Heterogeneous catalysis

Hydroxylation

Metallopolymers

Reactive oxygen species

Tyrosinase

American Studies

Arts and Humanities

Isolation, Characterization And Immobilization Of Polyphenol Oxidases From Mulberry (morus Alba) Leaf Tissues

Sutay, Didem

01 January 2003

In this study, the aim was to find an economical plant source for polyphenol oxidase (PPO) production as an alternative to mushroom and possible application areas by characterization and immobilization of the PPOs. For this purpose, tissues of various plants of no commercial value were screened for their PPO activities. Mulberry leaf tissues showed the highest PPO activity against 4-methyl catechol which was comparable to that of mushroom. Average Km and Vmax values of free mulberry leaf PPOs were found as 7 mM and 218 U/ml, respectively. Mulberry leaf PPOs were immobilized in a polypyrole matrix and the Km and Vmax values of immobilized PPOs were calculated as 35 mM and 3 U/ml, respectively. Mulberry leaf PPO was the most active at 45&deg / C and pH 7. By using electrophoretic analysis, laccase and catechol oxidase type activities of PPOs and in addition, peroxidase activity were detected. Molecular weights of laccase, peroxidase and catechol oxidase were found to be about 62, 64 and 62-64 kDa, with pI values of 8.0-8.5, 4.5 and 10, sequentially.

Phenolic compounds in oats : effects of steeping, germination and related enzymes /

Skoglund, Maria,

January 2008

Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniversitet, 2008. / Härtill 4 uppsatser.

Enzymology

Valiev, Abduvali

01 February 2007

In this study, two symbiotic fungi of Southern Pine Beetle (SPB), Entomocorticium peryii and Entomocorticium sp.A were evaluated in terms of polyphenol oxidase (PPO) production. The effect of different inhibitors, inducers and assay parameters such as temperature and pH on enzyme activity were investigated and maximum PPO activity was observed at 30&deg / C, pH 8.0 and when tannic acid was used as an inducer. Copper-chelator salicyl hydroxamic acid (SHAM) and pcoumaric acid, both indicated as inhibitors of tyrosinase and catechol oxidase significantly reduced the activity. For biochemical characterization studies, the enzyme was concentrated by ultrafiltration. To determine type of the enzyme, activity staining after Native-PAGE was carried out. Type of polyphenol oxidase produced by E. peryii and E. sp.A was determined as catechol oxidase by activity staining. However higher activity was observed on hydroquinone (p-diphenol) rather than catechol (o-diphenol). The enzyme obeys Michealis-Menten kinetics with Km and Vmaxvalues being 10.72 mM hydroquinone and 59.44 U/ml for E. peryii and 8.55 mM hydroquinone and 73.72 U/ml for E. sp.A respectively..

Functional Materials and Chemistry Education: Biomimetic Metallopolymers, Photoresponsive Gels and Infrared Cameras

Green, Travis Cole

29 April 2020

No description available.

Chemistry

Educational Technology

Materials Science

Polymers

Science Education

metallopolymer

biomimetic

catechol oxidase

indigo

photochemistry

infrared thermography

education

Ultrastructural and Histochemical Characterization of the Zebra Mussel Adhesive Apparatus

Farsad, Nikrooz

06 April 2010

Since their accidental introduction into the Great Lakes in mid- to late-1980s, the freshwater zebra mussels, Dreissena polymorpha, have colonized most lakes and waterways across eastern North America. Their rapid spread is partly attributed to their ability to tenaciously attach to hard substrates via an adhesive apparatus called the byssus, resulting in serious environmental and economic impacts. A detailed ultrastructural study of the bysuss revealed a 10 nm adhesive layer at the attachment interface. Distributions of the main adhesive amino acid, 3,4-dihydroxyphenylalanine (DOPA), and its oxidizing (cross-linking) enzyme, catechol oxidase, were determined histochemically. It was found that, upon aging, DOPA levels remained high in the portion of the byssus closest to the interface, consistent with an adhesive role. In contrast, reduced levels of DOPA corresponded well with high levels of catechol oxidase in the load-bearing component of the byssus, presumably forming cross-links and increasing the cohesive strength.

Zebra Mussel

Dreissena polymorpha

byssus

ultrastructure

bioadhesive

adhesive

3,4-dihydroxyphenylalanine

DOPA

TEM

transmission electron microscopy

bio-adhesive

catechol oxidase

immunogold labeling

histochemistry

histochemical methods

adhesive plaque

cryoultramicrotomy

TEM biological sample preparation

0794

0487

0306

Ultrastructural and Histochemical Characterization of the Zebra Mussel Adhesive Apparatus

Farsad, Nikrooz

06 April 2010

Since their accidental introduction into the Great Lakes in mid- to late-1980s, the freshwater zebra mussels, Dreissena polymorpha, have colonized most lakes and waterways across eastern North America. Their rapid spread is partly attributed to their ability to tenaciously attach to hard substrates via an adhesive apparatus called the byssus, resulting in serious environmental and economic impacts. A detailed ultrastructural study of the bysuss revealed a 10 nm adhesive layer at the attachment interface. Distributions of the main adhesive amino acid, 3,4-dihydroxyphenylalanine (DOPA), and its oxidizing (cross-linking) enzyme, catechol oxidase, were determined histochemically. It was found that, upon aging, DOPA levels remained high in the portion of the byssus closest to the interface, consistent with an adhesive role. In contrast, reduced levels of DOPA corresponded well with high levels of catechol oxidase in the load-bearing component of the byssus, presumably forming cross-links and increasing the cohesive strength.

Zebra Mussel

Dreissena polymorpha

byssus

ultrastructure

bioadhesive

adhesive

3,4-dihydroxyphenylalanine

DOPA

TEM

transmission electron microscopy

bio-adhesive

catechol oxidase

immunogold labeling

histochemistry

histochemical methods

adhesive plaque

cryoultramicrotomy

TEM biological sample preparation

0794

0487

0306

Biomimetic Studies on Tyrosine- and Phenolate- Based Ligands and their Metal Complexes

Umayal, M

January 2014

Tyrosine (4-hydroxyphenylalanine) is one of the naturally occurring 22 amino acids. The importance of tyrosine is due to the presence of its phenolic side chain. In biological systems, the tyrosyl residue in proteins is found to be sulfated, phosphorylated and nitrated. Upon oxidation with dioxygenases, Tyr residue forms dopaquinone which undergoes a series of reactions ultimately leading to the formation of melanin. Tyr is also a precursor to neurotransmitters (catechol amines namely dopamine, epinephrine and norepinephrine) and thyroid harmones T4 and T3. Tyr residue is also found to be cross linked with other amino acid residues in the active site of certain proteins. Tyr-Tyr cross link has also been associated with neurodegenerative diseases. Tyr residue in proteins has been targeted widely for site selective modifications. A series of chemical modifications like acylation, allylation, ene-type reaction, iodination with radiolabeled iodine, formation of Tyr-Tyr cross link with oxidants and aminoalkylation have been carried out on surface exposed Tyr residues in proteins. Apart from these chemical modifications of Tyr on protein surface, a couple of free Tyr-based scaffolds have also been developed for different applications. Similar to tyrosine-based scaffolds, several phenolate-based scaffolds have also been developed for various applications. Several phenolate-based binuclear metal complexes have been developed as mimics of the active site of metalloenzymes. Moreover, by varying the substituent in the phenolate scaffold, the redox properties of metal bound in these systems can be tuned. The thesis consists of five chapters. The first chapter gives general idea about tyrosine-and phenolate-based scaffolds. The first chapter also gives introduction to zinc(II)-containing enzymes metallo-β-lactamases (mβls) and phosphotriesterase (PTE) and their functional mimics. The importance of copper(II)-containing enzyme, catechol oxidase and its mimics has also been discussed. The significance and formation of o-dityrosine (Tyr-Tyr cross link) has also been briefly discussed. In chapters 2 and 3, a couple of phenolate-based ligands and their corresponding zinc(II)- and copper(II)- complexes have been synthesized and have been checked as mimics of zinc(II)-containing enzymes (mβl and PTE) and copper-containing enzyme catechol oxidase, respectively. In chapter 4, a series of tyrosine-based ligands have been designed and their in situ copper(II) complexes have been tested as mimics of catechol oxidase. In chapter 5, the effect of neighboring amino acid in the formation of Tyr-Tyr cross link has been studied. In chapter 2, a couple of zinc(II) complexes have been synthesized and studied as mimic of zinc(II)-containing enzymes mβl and PTE. Metallo-β-lactamases (mβls) are zinc(II)-containing enzymes which exist in both mono- and binuclear forms. Mβls are capable of hydrolyzing β-lactam ring in antibiotics and make them inactive (Scheme 1(A)). To date, an effective inhibitor for this enzyme is not known. Hence, in order to understand the nature of the enzyme a couple of synthetic mimics are known. However, in most of the synthetic mimics both the metal ions are in symmetrical environment. Therefore, we have attempted to design a few unsymmetrical phenolate- based ligands and their zinc(II) complexes. The unsymmetrical phenolate-based ligands HL1 and HL2 have been synthesized by sequential mannich reaction with formaldehyde and two different amines. Complexes 1 and 2 are obtained from ligands HL1 and HL2, respectively (Figure 1). For comparative purpose, the symmetrical ligands HL3 and HL4, and their zinc(II)-complexes 3 and 4 have been synthesized by reported procedures (Figure 1). The efficiency of the complexes 1-4 towards the hydrolysis of oxacillin has been studied. It has been observed that the binuclear zinc(II) complexes with metal-bound water molecule 1 and 4 are able to hydrolyze oxacillin at much faster rates compared to that of mononuclear complexes 2 and 3. However, between 1 and 4, there is no appreciable change in activity, indicating that the slight change in ligand environment has no significant role. PTE is a binuclear zinc(II)-containing enzyme, capable of hydrolyzing toxic organphosphotriesters to less toxic diesters (Scheme 1(B)). As the binuclear active site of mβl is comparable with that of phosphotriesterase (PTE), PTE activity of complexes 1-4 has been studied. Although the binuclear zinc(II)-complexes 1 and 4 are able to hydrolyze PNPDPP (p-nitrophenyl diphenyl phosphate) initially, these complexes are not able to effect complete hydrolysis. This is due to the inhibition of complexes 1 and 4 by hydrolyzed product, diester. However with mononuclear complexes 2 and 3 no such inhibitions is possible, and are capable of hydrolyzing PNPDPP at comparatively faster rates than 1 and 4. Scheme 1. Function of metallo-β-lactamase and phosphotriesterase. (A) Hydrolysis of β-lactam ring in antibiotics by metallo-β-lactamase. (B) Hydrolysis of organophosphotriesters to diesters by phosphotriesterase. Figure 1. Chemical structures of ligands HL1-HL4 and their corresponding zinc(II)complexes 1-4. In chapter 3, a couple of copper(II) complexes have been synthesized and their catechol oxidase activity has been studied. Catechol oxidase belongs to the class of oxidoreductase and it catalyzes the oxidation of a wide range of o-diphenols to o-quinones through the reduction of molecular oxygen to water (Scheme 2). A four new µ4-oxo-bridged tetranuclear copper(II) complexes (5-8) have been synthesized (Figure 2). The ability of these complexes to catalyze the oxidation of 3,5-DTBC (3,5-Di-tert-butylcatechol) to 3,5-DTBQ (3,5-Di-tert-butylquinone) has been studied. A detailed kinetic study has been carried out which reveals that the complexes with exogenous acetate ligands (5 and 6) are better catechol oxidase mimics compared to complexes with exogenous chloride ligands (7 and 8). This observation is due to the labile nature of acetate compared to chloride, as the displacement of exogenous ligand is essential for the binding of substrate to the catalyst. Based on mass spectral analysis a plausible mechanism has been proposed for the oxidation of 3,5-DTBC by these complexes. Scheme 2. Oxidation of catechol by catechol oxidase. Figure 2. Chemical structures of copper(II) complexes 5-8. In chapter 4, by following the analogy between phenol and tyrosine, a series of binucleating ligands of tyrosine or tyrosyl dipeptides (Figures 3 and 4) have been synthesized by Mannich reaction under mild conditions. The in situ complexation of these fifteen new binucleating ligands (HL5-HL19) with copper(II) chloride has been observed. In situ complexation was followed by UV-visible and mass spectral analysis. These in situ complexes were able to oxidize 3,5-DTBC at slower rate compared to that of the tetranuclear complexes reported in chapter 3. The catecholase activity has also been tested with the addition of base. A slight enhancement in activity of in situ complexes has been observed in the presence of base. Based on mass spectral evidences, a plausible mechanism for the oxidation of catechol by these in situ complexes has been proposed. Figure 3. Binucleating ligands (Mannich bases) of boc-protected tyrosine and tyrosyl dipeptides. Figure 4. Binucleating ligands (Mannich bases) of boc-deprotected tyrosyl dipeptides. In chapter 5 of the thesis, the effect of neighboring amino acid residue in the formation of o,o-dityrosine (Tyr-Tyr cross link) has been studied. o,o’-Dityrosine is a specific marker for oxidative/nitrosative stress. The increase in concentration of dityrosine is associated with several disease states. A detailed study has been carried out in order to find out the effect of neighboring amino acid residues in the rate of formation of dityrosine of several tyrosyl dipeptides. The formation of dityrosine has been carried out with horseradish peroxidase(HRP) and H2O2 (Scheme 3). Except Cys-Tyr, all other tyrosyl dipeptides, form corresponding dityrosine with HRP/ H2O2. With Cys-Tyr, the formation of corresponding disulfide is observed. The appreciably higher rate of dityrosine formation of Phe-Tyr is attributed to the presence of strong hydrophobic environment around the active site of HRP. Among the polar tyrosyl peptides, the positively charged peptides (Arg-Tyr, Lys-Tyr) undergo dityrosine formation at much faster rate compared to that of negatively charged dipepptides (Asp-Tyr, Glu-Tyr). This trend is in accordance with the pKa of neighboring amino acid residues. The positively charged neighboring residues with higher pKa stabilizes ionized tyrosine, hence the rate of dityrosine formation is higher for them. As positively charged neighboring residue enhances the rate of dityrosine formation, the effect of externally added L-Arg has been studied. A coupling of a few biologically relevant tyrosine derivatives has been studied. The derivatives in which one of the ortho-positions of tyrosine is blocked, does not undergo coupling under the experimental conditions employed. Scheme 3. Formation of dityrosine of Ile-Tyr from Ile-Tyr in the presence of H2O2 catalyzed by HRP. (For structural formula and figures pl refer the abstract pdf file)

Biomimetics

Tyrosine based Ligands

Metallo-β-Lactamase

Catechol Oxidase

Phenolate based Ligands

Copper Complexes

Zinc(II) Complexes

Phenolate-based Copper(II) Complexes

Tyrosine-based Copper Complexes

Phenolate-based Metal Complexes

Tyrosine-based Metal Complexes

Phenolate-based Zinc Complexes

Tyrosine-based Scaffolds

Phenolate-based Scaffolds

Tyrosyl Dipeptides

Bioinorganic Chemistry