Analysis and Interpretation of the Action Mechanism of Mushroom Tyrosinase on Monophenols and Diphenols Generating Highly Unstable O-quinones

Overview

Journal Biochim Biophys Acta

Specialties Biochemistry
Biophysics

Date 2001 Jul 14

PMID 11451433

Citations 15

Authors

L G Fenoll

J N Rodriguez-Lopez

F Garcia-Sevilla

P A Garcia-Ruiz

R Varon

F Garcia-Canovas

J Tudela

Affiliations

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Abstract

Tyrosinase can act on monophenols because of the mixture of met- (E(m)) and oxy-tyrosinase (E(ox)) which exists in the native form of the enzyme. The latter form is active on monophenols, while the former is not. However, the kinetics are complicated because monophenols can bind to both enzyme forms. This situation becomes even more complex since the products of the enzymatic reaction, the o-quinones, are unstable and continue evolving to generate o-diphenols in the medium. In the case of substrates such as L-tyrosine, tyrosinase generates very unstable o-quinones, in which a process of cyclation and subsequent oxidation-reduction generates o-diphenol through non-enzymatic reactions. However, the release of o-diphenol through the action of the enzyme on the monophenol contributes to the concentration of o-diphenol in the first pseudo-steady-state [D(0)](ss). Hence, the system reaches an initial pseudo-steady state when t-->0 and undergoes a transition phase (lag period) until a final steady state is reached when the concentration of o-diphenol in the medium reaches the concentration of the final steady state [D(f)](ss). These results can be explained by taking into account the kinetic and structural mechanism of the enzyme. In this, tyrosinase hydroxylates the monophenols to o-diphenols, generating an intermediate, E(m)D, which may oxidise the o-diphenol or release it directly to the medium. We surmise that the intermediate generated during the action of E(ox) on monophenols, E(m)D, has axial and equatorial bonds between the o-diphenol and copper atoms of the active site. Since the orbitals are not coplanar, the concerted oxidation-reduction reaction cannot occur. Instead, a bond, probably that of C-4, is broken to achieve coplanarity, producing a more labile intermediate that will then release the o-diphenol to the medium or reunite it diaxially, involving oxidation to o-quinone. The non-enzymatic evolution of the o-quinone would generate the o-diphenol ([D(f)](ss)) necessary for the final steady state to be reached after the lag period.

Citing Articles

Molecular Docking Studies of Ortho-Substituted Phenols to Tyrosinase Helps Discern If a Molecule Can Be an Enzyme Substrate.

Montenegro M, Teruel J, Garcia-Molina P, Tudela J, Rodriguez-Lopez J, Garcia-Canovas F Int J Mol Sci. 2024; 25(13).

PMID: 39000001 PMC: 11241521. DOI: 10.3390/ijms25136891.

Considerations about the Continuous Assay Methods, Spectrophotometric and Spectrofluorometric, of the Monophenolase Activity of Tyrosinase.

Garcia-Molina P, Munoz-Munoz J, Ortuno J, Rodriguez-Lopez J, Garcia-Ruiz P, Garcia-Canovas F Biomolecules. 2021; 11(9).

PMID: 34572482 PMC: 8465126. DOI: 10.3390/biom11091269.

Spectrophotometric Assays for Sensing Tyrosinase Activity and Their Applications.

Fan Y, Zhu S, Hou F, Zhao D, Pan Q, Xiang Y Biosensors (Basel). 2021; 11(8).

PMID: 34436092 PMC: 8393227. DOI: 10.3390/bios11080290.

Real-time fluorometric monitoring of monophenolase activity using a matrix-matched calibration curve.

Du D, Guo N, Zhang L, Wu Y, Shang Q, Liu W Anal Bioanal Chem. 2020; 413(2):635-647.

PMID: 33159571 DOI: 10.1007/s00216-020-03034-4.

Catalysis-based specific detection and inhibition of tyrosinase and their application.

Qu Y, Zhan Q, Du S, Ding Y, Fang B, Du W J Pharm Anal. 2020; 10(5):414-425.

PMID: 33133725 PMC: 7591782. DOI: 10.1016/j.jpha.2020.07.004.