The effects of pH and various salts upon the activity of a series of superoxide dismutases

O’Neill, Peter; Davies, Sarah; Fielden, E.M.; Calabrese, Lilia; Capo, Concetta; Marmocchi, Franco; Natoli, Guido; Rotilio, Giuseppe

doi:10.1042/bj2510041

Cited by 70 publications

(52 citation statements)

References 26 publications

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“…The bmSOD was stable in a wide pH rage under the experimental condition and the stability was similar to those of SODs. [42][43][44] Successful construction of the overproduction system of rSOD makes further characterization and studies including Western blot analysis possible. Fat bodies was dissected at various times after irradiation by gamma rays at 10 Gy ( ), 50 Gy ( ), and 100 Gy ( ), and proteins were extracted (see ''Materials and Methods'').…”

Section: Discussionmentioning

confidence: 99%

Superoxide Dismutase from the Silkworm,Bombyx mori: Sequence, Distribution, and Overexpression

Yamamoto

Zhang

Banno

et al. 2005

Bioscience, Biotechnology, and Biochemistry

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Section: Discussionmentioning

confidence: 99%

Superoxide Dismutase from the Silkworm,Bombyx mori: Sequence, Distribution, and Overexpression

Yamamoto

Zhang

Banno

et al. 2005

Bioscience, Biotechnology, and Biochemistry

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“…This result indicates either that neutralization of Lysl20 allows the occurrence of new diffusion pathways of the substrate toward the active site or that eukaryotic Cu,Zn SODs, although displaying a very similar three-dimensional structure, are characterized by subtle changes that may produce a different modulation of the electrostatic attraction of the negatively charged substrate toward the active site. A common effect observed in all the natural and mutant Cu,Zn SOD eukaryotic variants studied so far is the large decrease of the catalytic rate upon increasing the ionic strength (O'Neill et al, 1988;Getzoff et al, 1992;Polticelli et al, 1995;Fisher et al, 1997). In the case of X. Zaevis SOD, as for bovine and human SODs, the net charge is negative (-6e for X .…”

Section: Fig 2 Electrostatic Potential Distribution Around (A) Lqqtmentioning

confidence: 99%

Role of the electrostatic loop charged residues in Cu, Zn superoxide dismutase

et al. 1998

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We have expressed and characterized a mutant of Xenopus laevis Cu,Zn superoxide dismutase in which four highly conserved charged residues belonging to the electrostatic loop have been replaced by neutral side chains: Lysl20 + Leu, Asp130 + Gln, Glu131 + Gln, and Lys134 -+ Thr. At low ionic strength, the mutant enzyme is one of the fastest superoxide dismutases ever assayed (k = 6.7 X 10' M" s-' , at pH 7 and p = 0.02 M). Brownian dynamics simulations give rise to identical enzyme-substrate association rates for both wild-type and mutant enzymes, ruling out the possibility that enhancement of the activity is due to pure electrostatic factors. Comparative analysis of the experimental catalytic rate of the quadruple and single mutants reveals the nonadditivity of the mutation effects, indicating that the hyperefficiency of the mutant is due to a decrease of the energy barrier and/or to an alternative pathway for the diffusion of superoxide within the active site channel. At physiological ionic strength the catalytic rate of the mutant at neutral pH is similar to that of the wild-type enzyme as it is to the catalytic rate pH dependence. Moreover, mutation effects are additive. These results show that, at physiological salt conditions, electrostatic loop charged residues do not influence the diffusion pathway of the substrate and, if concomitantly neutralized, are not essential for high catalytic efficiency of the enzyme, pointing out the role of the metal cluster and of the invariant Arg 141 in determining the local electrostatic forces facilitating the diffusion of the substrate towards the active site.

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“…The pH of the sample solution for each spectral measurement was obtained using a micro-combination pH electrode (Microelectrodes, Inc.). Curve-fitting procedures were performed to obtain the best fits of the data based on the pH-dependent activity, spectral changes and dissociation constants of azide being governed by one prototrophic equilibrium, Ka [22]. The following equations were used to obtain the best fits: (Whatman Chemical Separation) column (1 cm X 2 cm), previously equilibrated with 10 mM potassium phosphate, pH 7.8.…”

Section: Methodsmentioning

confidence: 99%

The pH‐Dependent Changes of the Enzymic Activity and Spectroscopic Properties of Iron‐Substituted Manganese Superoxide Dismutase

Yamakura

Kobayashi

et al. 1995

European Journal of Biochemistry

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Manganese-containing superoxide dismutases (Mn-SODs) and iron-containing superoxide dismutases (Fe-SODS) from aerobic bacteria often show high metal specificity for their enzymic activities by a standard assay system using xanthine-xanthine oxidase and cytochrome c. In this study, we have attempted to characterize the structural basis of the metal specificity of manganese-containing SOD (Mn-SOD) using Fe-substituted Mn-SOD prepared from apo-Mn-SOD from Serratia marcescens. The Fe3+ content of the Fe-substituted enzyme was 1.71 t 0.14 mol/mol dimer and the specific activity was 34.8 -C 4.8 units . mg protein-' . mol Fe3+-' . mol subunit-'. Fe-substituted Mn-SOD was found to react with the superoxide anion at pH 8.1 with a second-order rate constant of 6X lo6 M-' SK', which is approximately 1 % of that Iof native Mn-SOD at the same pH. However, the rate constant increased with decreasing pH to approximately 10% (5X107 MK1 s-') that of native Mn-SOD at pH 6.0 with a pK of 7.0, The visible absoIption spectrum and EPR spectrum of Fe-substituted Mn-SOD also showed pH-dependent changes with pK values of 6.6 and 7.2, respectively. Similarly, the affinity of the azide ion, an analog of the superoxide ion, for iron of Fe-substituted Mn-SOD increased with decreasing pH, with a pK value of 7.0 (e.g. Kd =0.1 mM at pH 6 . 2 and 0.9 mM at pH 8.2). The similarity of these pK values suggests that the activity, the spectral changes and the affinity of the azide ion for iron are derived from the same change in the metal environment. After comparison with the reported pK values (around 9) of similar pH-dependent changes in the spectra, the enzymic activity and the affinity of azide for iron of Fe-SOD from Escherichia coli, we proposed that the difference in the pK values of a hydroxide ion binding to iron between Fe-substituted Mn-SOD and Fe-SOD may cause the different pH dependencies of these changes in each SOD.Keywords. Superoxide dismutase; manganese; iron-substitution; metal-specificity ; Serratia murcescens.Three classes of superoxide dismutase (SOD) have been reported, based on their active-site metals ; copper-and zinc-containing superoxide dismutase (Cu, Zn-SOD), iron-containing SOD (Fe-SOD) and manganese-containing SOD (Mn-SOD [5] have been shown to have similar amino acid sequences, three-dimensional structures and trigonal pyramidal metal-site geometries. The iron and manganese atoms in these Fe-SODS and Mn-SODS are commonly ligated by three histidine residues and one aspartic acid residue. Previous reconstitution experiments, however, indicated that the metal requirements for enzymic activity of the Fe-SODS from R ovalis 161 and Photobacterium leiognathi [7] Correspondence 10 F. Yamdkura, Department of Chemistry, School of Medicine, Juntendo University, 1-1 Hiraga-gakuendai, Inba-gun, Chiba, Japan 270-1 6Fax: +81 476 98 1036. Abbreviations. SOD, superoxide dismutase; Cu, Zn-SOD, copper and zinc-containing superoxide dismutase ; Fe-SOD, iron-containing superoxide dismutase ; hh-SOD, manganese-containing superoxide dism...

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The effects of pH and various salts upon the activity of a series of superoxide dismutases

Cited by 70 publications

References 26 publications

Superoxide Dismutase from the Silkworm,Bombyx mori: Sequence, Distribution, and Overexpression

Superoxide Dismutase from the Silkworm,Bombyx mori: Sequence, Distribution, and Overexpression

Role of the electrostatic loop charged residues in Cu, Zn superoxide dismutase

The pH‐Dependent Changes of the Enzymic Activity and Spectroscopic Properties of Iron‐Substituted Manganese Superoxide Dismutase

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