Chemical, Spectroscopic and Structural Investigation of the Substrate‐Binding Site in Ascorbate Peroxidase

Hill, Adrian P.; Modi, Sandeep; Sutcliffe, Michael J.; Turner, Daniel D.; Gilfoyle, David J.; Smith, Andrew T.; Tam, Beatrice M.; Lloyd, E. A.

doi:10.1111/j.1432-1033.1997.00347.x

Cited by 32 publications

(42 citation statements)

References 84 publications

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“…1 mmol l −1 (Shigeoka et al, 2002). However, a structural study by Hill et al (Hill et al, 1997) showed that APX had a binding (dissociation) constant to the enzyme of K d =11.6 μmol l −1 and it is entirely reasonable that APX was inhibited in our experiments.…”

Section: The Effect Of Calvin-benson Cycle Inhibition On Coral Bleachingmentioning

confidence: 52%

Inhibition of photosynthetic CO2 fixation in the coral Pocillopora damicornis and its relationship to thermal bleaching

Hill

Szabó

Rehman

et al. 2014

Journal of Experimental Biology

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Two inhibitors of the Calvin-Benson cycle [glycolaldehyde (GA) and potassium cyanide (KCN)] were used in cultured Symbiodinium cells and in nubbins of the coral Pocillopora damicornis to test the hypothesis that inhibition of the Calvin-Benson cycle triggers coral bleaching. Inhibitor concentration range-finding trials aimed to determine the appropriate concentration to generate inhibition of the Calvin-Benson cycle, but avoid other metabolic impacts to the symbiont and the animal host. Both 3 mmol l(-1) GA and 20 μmol l(-1) KCN caused minimal inhibition of host respiration, but did induce photosynthetic impairment, measured by a loss of photosystem II function and oxygen production. GA did not affect the severity of bleaching, nor induce bleaching in the absence of thermal stress, suggesting inhibition of the Calvin-Benson cycle by GA does not initiate bleaching in P. damicornis. In contrast, KCN did activate a bleaching response through symbiont expulsion, which occurred in the presence and absence of thermal stress. While KCN is an inhibitor of the Calvin-Benson cycle, it also promotes reactive oxygen species formation, and it is likely that this was the principal agent in the coral bleaching process. These findings do not support the hypothesis that temperature-induced inhibition of the Calvin-Benson cycle alone induces coral bleaching.

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Section: The Effect Of Calvin-benson Cycle Inhibition On Coral Bleachingmentioning

confidence: 52%

Inhibition of photosynthetic CO2 fixation in the coral Pocillopora damicornis and its relationship to thermal bleaching

Hill

Szabó

Rehman

et al. 2014

Journal of Experimental Biology

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“…Enzyme purity was additionally assessed using SDS/PAGE, and the preparations were judged to be homogeneous by the observation of a single band on a Coomassie Blue‐stained reducing SDS/polyacrylamide gel. Enzyme concentrations (pH 7.0, µ = 0.10 m , 25.0 °C) were determined using the pyridine haemochromagen method [39]: absorption coefficients were ε 403 = 88 m m −1 ·cm −1 for rAPX [40], ε 397 = 83 m m −1 ·cm −1 for H42A and ε 404 = 95 m m −1 ·cm −1 for H42E.…”

Section: Methodsmentioning

confidence: 99%

Role of histidine 42 in ascorbate peroxidase

Lad¹,

Mewies²,

Basran

et al. 2002

European Journal of Biochemistry

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To examine the role of the distal His42 residue in the catalytic mechanism of pea cytosolic ascorbate peroxidase, two site-directed variants were prepared in which His42 was replaced with alanine (H42A) or glutamic acid (H42E). Electronic spectra of the ferric derivatives of H42A and H42E (pH 7.0, l ¼ 0.10 M, 25.0°C) revealed wavelength maxima [k max (nm): 397, 509, % 540 sh , 644 (H42A); 404, 516, % 538 sh , 639 (H42E)] consistent with a predominantly fiveco-ordinate high-spin iron. The specific activity of H42E for oxidation of L-ascorbate (8.2 ± 0.3 UAEmg )1 ) was % 30-fold lower than that of the recombinant wild-type enzyme (rAPX); the H42A variant was essentially inactive but activity could be partially recovered by addition of exogenous imidazoles. The plant peroxidase superfamily has been classified [1] into three major categories: class I contains the enzymes of prokaryotic origin, class II contains the fungal enzymes (e.g. manganese peroxidase, lignin peroxidase) and class III contains the classical secretory peroxidases [e.g. horseradish peroxidase (HRP)]. The most notable member of the class I peroxidase subgroup is cytochrome c peroxidase (CcP), which was first identified in 1940 [2]. In spite of the fact that CcP has some rather unusual features, most notably the existence of a stable tryptophan radical during catalysis [3][4][5][6] and the utilization of a large macromolecular substrate (cytochrome c), it has been the subject of such intense mechanistic, structural and spectroscopic scrutiny that it has become the benchmark against which all other peroxidases are measured.More recently, it has been possible to isolate and purify in good yields a second member of the class I peroxidase subgroup, ascorbate peroxidase (APX) [7,8]. Ascorbatedependent peroxidase activity was first reported in 1979 [9,10] and the enzyme catalyses the reduction of potentially damaging H 2 O 2 in plants and algae using ascorbate as a source of reducing equivalents [11,12]. APX was known from sequence comparisons [13] to contain the same activesite Trp residue (Trp179) as is used by CcP (Trp191) during catalysis. With high-resolution structural information available for the recombinant pea cytosolic enzyme (rAPX) [14] ( Fig. 1), APX has provided a new opportunity to reassess the functional properties of CcP and to determine whether it is indeed representative of class I peroxidases. As detailed functional information has emerged, however, it seems that APX has several rather curious features of its own, and, in some ways, more questions have been raised than answered. (In fact, even the current classification of APX as a class I enzyme has been recently questioned [15].) For example, Trp179 in APX is not a necessary requirement for oxidation of ascorbate [16] and there is general agreement from kinetic [17][18][19] and EPR data [20] that the initial product (Compound I) of the reaction of APX with H 2 O 2 is a porphyrin p-cation intermediate and not a protein-based trytophan radical. Equally intriguing is the existence of a

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“…The domains are connected via helix E. On the basis of the results from nuclear magnetic resonance and computer-modeling, the ascorbate-binding site has been proposed to be in a pocket formed by the heme molecule and the domain I. 6) On the basis of enzyme characteristics and amino acid sequences, APXs of higher plants have been divided into several isoforms; 7) two soluble isoforms in the cytosol and the stroma, and two membranebound isoforms localized in the thylakoids and the microbodies (glyoxysome and peroxisome). Theˆfth isoform, the subcellular localization of which remains unknown, has also been found.…”

mentioning

confidence: 99%

Stable Form of Ascorbate Peroxidase from the Red AlgaGaldieria partitaSimilar to Both Chloroplastic and Cytosolic Isoforms of Higher Plants

Kitajima¹,

Ueda²,

Сано³

et al. 2002

Bioscience, Biotechnology, and Biochemistry

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Depletion of the electron donor ascorbate causes rapid inactivation of chloroplastic ascorbate peroxidase (APX) of higher plants, while cytosolic APX is stable under such conditions. Here we report the cloning of cDNA from Galdieria partita, a unicellular red alga, encoding a novel type of APX (APX-B). The electrophoretic mobility, Km values, kcat and absorption spectra of recombinant APX-B produced in Escherichia coli were measured. Recombinant APX-B remained active for at least 180 min after depletion of ascorbate. The amino-terminal half of APX-B, which forms the distal pocket of the active site, was richer in amino acid residues conserved in chloroplastic APXs of higher plants rather than cytosolic APXs. In contrast, the sequence of the carboxyl-terminal half, which forms the proximal pocket, was similar to that of the cytosolic isoform. The stability of APX-B might be due to its cytosolic isoform-like structure of the carboxyl-terminal half.

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Chemical, Spectroscopic and Structural Investigation of the Substrate‐Binding Site in Ascorbate Peroxidase

Cited by 32 publications

References 84 publications

Inhibition of photosynthetic CO2 fixation in the coral Pocillopora damicornis and its relationship to thermal bleaching

Inhibition of photosynthetic CO2 fixation in the coral Pocillopora damicornis and its relationship to thermal bleaching

Role of histidine 42 in ascorbate peroxidase

Stable Form of Ascorbate Peroxidase from the Red AlgaGaldieria partitaSimilar to Both Chloroplastic and Cytosolic Isoforms of Higher Plants

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