A DyP-type peroxidase at a bio-compatible interface: structural and mechanistic insights

Sezer, Murat; Genebra, Tânia; Mendes, Sónia; Martins, Lı́gia O.; Todorović, Smilja

doi:10.1039/c2sm26310f

Cited by 22 publications

(73 citation statements)

References 58 publications

(124 reference statements)

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“…This assignment is consistent with the frequencies reported in the literature for catalytic intermediates of classical peroxidases. [11][12][13][14][15][16] In the absence of the reference RR spectra of Cpd I and Cpd II in DyPs, the assignment of the 1378 cm À1 and 1508 cm À1 modes to the oxyferryl Fe(IV)QO porphyrin p cation is supported by the evidence from our previous work: (i) electronic absorption spectra, which reveal a fingerprint of stable Cpd I in the reaction of PpDyP with 1-3 equivalents of H 2 O 2 in solution; [8][9][10] 8 The n 4 /n 3 values that we observe here are slightly higher than those reported for Cpd I in the literature, 11 which may be an intrinsic property of DyPs, or an indication of Cpd II. For instance, n 4 and n 3 modes of Cpd I in HRP were found at 1373-1376 and 1505 cm À1 , respectively, but at 1379 and 1510 cm À1 in Cpd II.…”

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confidence: 61%

“…9,10 Component analysis of the spectra reveals well resolved bands of the n 4 , n 3 , n 2 , n 10 and n CQC modes at 1376, 1502, 1572, 1626 and 1637 cm À1 (Fig. 1a, green trace) and at 1373, 1494, 1564, 1621 and 1632 cm À1 (Fig.…”

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confidence: 97%

“…solution vs. crystalline form) induce a typically reversible inter-conversion of the spin populations. 9,10,18,19 Upon addition of 1 equivalent of hydrogen peroxide to the SERR cell holding the enzyme-loaded metal support, well reproducible spectral changes occur instantaneously: a pronounced decrease of signal intensity, accompanied by an upshift of n 4 and n 3 modes and a broadening of n 2 , n 10 and n CQC bands (Fig. S1, ESI †).…”

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confidence: 99%

“…[1][2][3][4][5][6][7][8][9][10] They lack the distal histidine that is highly conserved in classical peroxidases and which acts as an acid/base catalyst in the reduction of hydrogen peroxide to water. DyPs are classified into four phylogenetically distinct classes (A-D); their physiological role is not fully established yet and it appears to be subfamilydependent.…”

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confidence: 99%

“…1a, blue trace), which are attributed to quantum mechanically mixed-spin (QS) and 5-coordinated high spin (5cHS) species, respectively. 9,10 In addition, small contributions of a 6-coordinated HS (6cHS) species with n 4 at 1366 cm À1 and n 3 at 1483 cm À1 are also present in the spectra. The SERR spectra of PpDyP immobilised on Ag supports coated with mixed amino-and hydroxyl-terminated alkanethiol self-assembled monolayers (SAM), employing aminooctanethiol (AOT) and mercaptohexanol (MOH) in a 1 : 3 (M/M) ratio, reveal essentially the same band frequencies as RR spectra ( Fig.…”

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confidence: 99%

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Surface enhanced resonance Raman detection of a catalytic intermediate of DyP-type peroxidase

Todorović

Hildebrandt

Martins

2015

Phys. Chem. Chem. Phys.

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We report herein the vibrational spectroscopic characterisation of a catalytic intermediate formed by the reaction of H 2 O 2 with DyP-type peroxidase immobilised on a biocompatible coated metal support.The SERR spectroscopic approach is of general applicability to other peroxidases which form relatively stable catalytic intermediates.Dye-decolourising peroxidases (DyPs) are novel heme peroxidases, the primary sequence, structural and mechanistic properties of which are unrelated to those of other known peroxidases. [1][2][3][4][5][6][7][8][9][10] They lack the distal histidine that is highly conserved in classical peroxidases and which acts as an acid/base catalyst in the reduction of hydrogen peroxide to water. DyPs are classified into four phylogenetically distinct classes (A-D); their physiological role is not fully established yet and it appears to be subfamilydependent. 1-10 DyP from Pseudomonas putida MET94 (PpDyP) is an extremely versatile B-type DyP, capable of efficient oxidation of a wide range of anthraquinonic and azo dyes, phenolic substrates, the non-phenolic veratryl alcohol and even manganese and ferrous ions. 8 In the reaction with H 2 O 2 , PpDyP forms a stable Compound I (Cpd I) at a rate of 1.4 AE 0.3 Â 10 6 M À1 s À1 , comparable to those of classical peroxidases and other DyPs. 8 The intermediate is, like in other DyPs, surprisingly long-living, with a half-life of B60 min, as demonstrated by electronic absorption spectroscopy. 9 Upon immobilisation on biocompatible metal supports, PpDyP is capable of efficient electrocatalytic activity in the presence of hydrogen peroxide. The enzyme is therefore a promising candidate for the design of bio-electronic devices with unique DyP-type peroxidase substrate specificity. 9,10 Resonance Raman (RR) spectroscopy has been extensively used in the detection and characterisation of peroxidase and catalase-peroxidase catalytic intermediates, and RR spectroscopic fingerprints of Cpd I (two equivalent oxidised resting ferric state) and Cpd II (one equivalent oxidised resting ferric state) are well established. [11][12][13][14][15][16] However, a strong fluorescence impeded the RR studies of PpDyP intermediates. Here, we have probed catalytic intermediate species of immobilised PpDyP by surface enhanced RR (SERR) spectroscopy. The SERR spectra of heme proteins immobilised on nanostructured Ag surfaces exclusively display the cofactor signals of the adsorbed molecules. In addition, close proximity of the molecule to the metal surface can efficiently quench fluorescence. 17 Like in RR spectroscopy, SERR signals include, inter alia, the core-size marker bands (e.g. n 4 , n 3 , n 2 , n 10 ) which are specifically enhanced upon excitation in resonance with the Soret absorption band of the porphyrin. The frequencies of these modes are indicative of the redox and spin states and the coordination pattern of the heme iron.We have previously shown that the high frequency region of RR spectra of the resting PpDyP in solution displays broad marker bands, indicative of t...

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confidence: 61%

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confidence: 97%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Surface enhanced resonance Raman detection of a catalytic intermediate of DyP-type peroxidase

Todorović

Hildebrandt

Martins

2015

Phys. Chem. Chem. Phys.

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Surface‐EnhancedRaman Scattering of Biological Materials

Todorović

Murgida

2016

Encyclopedia of Analytical Chemistry

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Surface‐enhanced Raman spectroscopy (SERS) is a very powerful vibrational method that can be applied to a variety of biological samples provided that drawbacks, such as poor reproducibility of the signal and biocompatibility of the substrates, can be satisfactorily overcome. SERS is characterized by very low limits of detection, mainly due to the electromagnetic enhancement of the Raman signals, capable of achieving the single‐molecule level. Moreover, the spectra of small molecules represent authentic molecular fingerprints with very narrow linewidths that, along with the additional enhancement and inter‐/intramolecular selectivity gained through resonant laser excitation (surface‐enhanced resonance Raman spectroscopy, SERRS), make this technique particularly suited for multiplexing applications in complex biological samples. In this article, we introduce first the physical principles of SER(R)RS and describe the different types of substrates, as well as the basic modern instrumentation. We then provide an overview of recent biological applications, including biophysical mechanistic and structural studies on isolated biomolecules, their direct and indirect detection, chemical imaging of biological samples, and biomedical applications. Finally, we briefly discuss our outlook for the future research in this field.

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Electrochemical Multiplexing: Control over Surface Functionalization by Combining a Redox‐Sensitive Alkyne Protection Group with “Click”‐Chemistry

Hellstern

Gantenbein

Puebla‐Hellmann

et al. 2019

Adv Materials Inter

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and molecular electronics, [11,12] over medical diagnostic devices [13][14][15] to applications tuning macroscopic and/or environmental features like, e.g., the wettability [16][17][18] or the biocompatibility [19][20][21] of material surfaces. In most cases, a bifunctional molecule, combining an anchor group attaching the molecular compound to the surface with an exposed subunit representing the active moiety with tailored physiochemical properties is used to tune the surface's terminal appearance. While such approaches are successfully applied for entire objects and surfaces of considerable dimensions and macroscopic separations, there are limitations as soon as spatial patterns of varying surface functionalities and microscopic separations are desired or a spatially constrained surface-access including buried microfluidic chips has to be overcome. For example, conventional wet chemical surface functionalization procedures are spatially limited to the size of the droplet deposited (and its subsequent surface interaction) and methods depositing the molecules from gas-phase in vacuum require advanced masking strategies. Challenging are devices with a variety of molecular features to be created in a parallel process and in a locally controlled manner, like, e.g., multidimensional sensing platforms where a multitude of nearby molecular receptors are screening analytes in parallel. Or microfluidic chips with constrained access to functional sites as the channels are locally enclosed and inaccessible for droplet deposition. Of great interest are devices analyzing molecular binding events electronically, due to their miniaturization potential and the analyte-selective binding without the requirement of labels. In such devices, each electrode is electrically addressable in a separated manner as they were contacted individually. Such a preexisting electrical wiring scheme is a unique feature for an immobilization strategy able to distinguish between the applied electrical potentials of each electrode and a common electrolyte. The electrochemical release of thiol-based self-assembled monolayers (SAMs) on gold electrodes has been reported. [22] This allows the disintegration of existing SAMs. The subsequent decoration of the liberated electrode with an alternative thiol-molecule, however, is handicapped by scrambling with the remaining SAMs. Electrochemical triggered constructive build-up of molecular Local functionalization of surfaces is a current technological challenge. An electrochemically addressable alkyne protection group is presented enabling the site-selective liberation of alkynes exclusively on electrified electrodes. This controlled deprotection is based on a mendione chromophore which becomes a strong enough nucleophile upon reduction to intramolecularly attack the trialkylsilane alkyne protection group. The site-selective liberation of the alkyne is demonstrated by immobilizing the protected alkyne precursor on a transparent TiO 2 electrode and subsequently immobilizing red and blue azide dyes by azide-alky...

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A DyP-type peroxidase at a bio-compatible interface: structural and mechanistic insights

Cited by 22 publications

References 58 publications

Surface enhanced resonance Raman detection of a catalytic intermediate of DyP-type peroxidase

Surface enhanced resonance Raman detection of a catalytic intermediate of DyP-type peroxidase

Surface‐EnhancedRaman Scattering of Biological Materials

Electrochemical Multiplexing: Control over Surface Functionalization by Combining a Redox‐Sensitive Alkyne Protection Group with “Click”‐Chemistry

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