María José Rodríguez Marañón scite author profile

The electronic structures of the cationic isoenzyme of peanut peroxidase, horseradish peroxidase (isoenzyme C) and bovine liver catalase are compared through analysis of their optical absorption and magnetic c.d. (m.c.d.) spectral properties. The spectral data for the native resting states and compounds I and II of peanut peroxidase (PeP) are reported. The absorption and m.c.d. data for the native PeP exhibit bands characteristic of the high-spin ferric haem. The absorption spectrum of PeP compound I closely resembles that observed for the HRP compound I species. The m.c.d. data for PeP I clearly identifies that ring oxidation has occurred. One-electron reduction forms the PeP compound II species. The absorption and m.c.d. spectra recorded for PeP II exhibit the well-resolved spectral characteristics previously observed for both HRP compound II and catalase compound II. The spectral data of PeP with HRP and catalase are compared. The data clearly indicate that the m.c.d. spectral patterns of both plant peroxidases (PeP and HRP) are very similar and, therefore, the electronic structures of their resting states, and as well their primary and secondary compounds, must be similar. The m.c.d. data suggest that, while the compound I species of PeP and HRP belong to one electronic class, catalase compound I belongs to a different class. These data emphasize how the ground states of these two classes of oxidized haem, may be characterized as predominantly 2A2u (PeP I and HRP I) or 2A1u (catalase I). Peanut peroxidase is the second plant peroxidase for which the electronic structure of the compound I intermediate has been studied using the m.c.d. technique. The similarities with horseradish peroxidase allow us to suggest that plant peroxidases may operate by the same general mechanism, in spite of the low degree of sequence similarity between their polypeptide chains.

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Structural Influence of Calcium on the Heme Cavity of Cationic Peanut Peroxidase as Determined by 1H-NMR Spectroscopy

Barber¹,

Marañón²,

Shaw³

et al. 1995

Eur J Biochem

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The cationic isozyme of peanut peroxidase (CPRx) is one of many peroxidases which requires calcium for enzyme activity. It has been previously shown that it requires 2 mol calcium to coordinate to 1 mol CPRx, and its related peroxidases from the basidiomycete Phanerochaete chrysosporium (Lip) and isozyme C of horseradish (HRPc). X‐ray crystallographic studies of LiP have shown that calcium is ligated near the C‐terminus of helices proximal and distal to the heme, where it has been suggested to maintain the active site. To determine if such a mechanism was possible in CPRx, high resolution 1H‐NMR spectroscopy was used to study the effect of calcium on the environment of its heme group and the coordinating histidine residues. The low‐spin cyano complex of the enzyme (CPRxCN) was studied in order to assign the majority of the resonances arising from the protons in the heme pocket in both the presence and absence of bound calcium ions using two dimensional nuclear Overhauser effect spectroscopy (NOESY). The two calcium ions present in CPRxCN were removed by a non‐denaturing method and a calcium titration was performed and monitored by 1H‐NMR spectroscopy. These studies showed that the binding of both calcium ions in CPRx influenced the heme environment in a similar manner (Kd= 0.1 μM). In particular, calcium‐dependent changes in several heme resonances and the proximal and distal histidine residues suggest that calcium binding to CPRx causes some reorientation of these residues with respect to the active site.

show abstract

Structural Influence of Calcium on the Heme Cavity of Cationic Peanut Peroxidase as Determined by 1H-NMR Spectroscopy

Barber¹,

Marañón²,

Shaw³

et al. 1995

Eur J Biochem

View full text Add to dashboard Cite

The cationic isozyme of peanut peroxidase (CPRx) is one of many peroxidases which requires calcium for enzyme activity. It has been previously shown that it requires 2 mol calcium to coordinate to 1 mol CPRx, and its related peroxidases from the basidiomycete Phanerochaete chrysosporium (LiP) and isozyme C of horseradish (HRPc). X-ray crystallographic studies of LiP have shown that calcium is ligated near the C-terminus of helices proximal and distal to the heme, where it has been suggested to maintain the active site. To determine if such a mechanism was possible in CPRx, high resolution 1H-NMR spectroscopy was used to study the effect of calcium on the environment of its heme group and the coordinating histidine residues. The low-spin cyano complex of the enzyme (CPRxCN) was studied in order to assign the majority of the resonances arising from the protons in the heme pocket in both the presence and absence of bound calcium ions using two dimensional nuclear Overhauser effect spectroscopy (NOESY). The two calcium ions present in CPRxCN were removed by a non-denaturing method and a calcium titration was performed and monitored by 1H-NMR spectroscopy. These studies showed that the binding of both calcium ions in CPRx influenced the heme environment in a similar manner (Kd = 0.1 microM). In particular, calcium-dependent changes in several heme resonances and the proximal and distal histidine residues suggest that calcium binding to CPRx causes some reorientation of these residues with respect to the active site.

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Structural Influence of Calcium on the Heme Cavity of Cationic Peanut Peroxidase as Determined by ¹H‐NMR Spectroscopy

Barber

Marañón

Shaw

et al. 1995

European Journal of Biochemistry

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The cationic isozyme of peanut peroxidase (CPRx) is one of many peroxidases which requires calcium for enzyme activity. It has been previously shown that it requires 2 mol calcium to coordinate to 1 mol CPRx, and its related peroxidases from the basidiomycete Phanerochaete chrysosporium (Lip) and isozyme C of horseradish (HRPc). X-ray crystallographic studies of Lip have shown that calcium is ligated near the C-terminus of helices proximal and distal to the heme, where it has been suggested to maintain the active site. To determine if such a mechanism was possible in CPRx, high resolution 'H-NMR spectroscopy was used to study the effect of calcium on the environment of its heme group and the coordinating histidine residues. The low-spin cyano complex of the enzyme (CPRxCN) was studied in order to assign the majority of the resonances arising from the protons in the heme pocket in both the presence and absence of bound calcium ions using two dimensional nuclear Overhauser effect spectroscopy (NOESY). The two calcium ions present in CPRxCN were removed by a non-denaturing method and a calcium titration was performed and monitored by 'H-NMR spectroscopy. These studies showed that the binding of both calcium ions in CPRx influenced the heme environment in a similar manner (Kd = 0.1 pM). In particular, calcium-dependent changes in several heme resonances and the proximal and distal histidine residues suggest that calcium binding to CPRx causes some reorientation of these residues with respect to the active site.

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