Martin Ph. Verbeet scite author profile

The homotrimeric copper-containing nitrite reductase (NiR) contains one type-1 and one type-2 copper center per monomer. Electrons enter through the type-1 site and are shuttled to the type-2 site where nitrite is reduced to nitric oxide. To investigate the catalytic mechanism of NiR the effects of pH and nitrite on the turnover rate in the presence of three different electron donors at saturating concentrations were measured. The activity of NiR was also measured electrochemically by exploiting direct electron transfer to the enzyme immobilized on a graphite rotating disk electrode. In all cases, the steady-state kinetics fitted excellently to a randomsequential mechanism in which electron transfer from the type-1 to the type-2 site is rate-limiting. At low [NO 2 ؊ ] reduction of the type-2 site precedes nitrite binding, at high [NO 2 ؊ ] the reverse occurs.Below pH 6.5, the catalytic activity diminished at higher nitrite concentrations, in agreement with electron transfer being slower to the nitrite-bound type-2 site than to the water-bound type-2 site. Above pH 6.5, substrate activation is observed, in agreement with electron transfer to the nitrite-bound type-2 site being faster than electron transfer to the hydroxyl-bound type-2 site. To study the effect of slower electron transfer between the type-1 and type-2 site, NiR M150T was used. It has a type-1 site with a 125-mV higher midpoint potential and a 0.3-eV higher reorganization energy leading to an ϳ50-fold slower intramolecular electron transfer to the type-2 site. The results confirm that NiR employs a random-sequential mechanism.

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Generalized glycogen storage and cardiomegaly in a knockout mouse model of Pompe disease

Bijvoet

Kamp

Kroos³

et al. 1998

Human Molecular Genetics

125

122

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Glycogen storage disease type II (GSDII; Pompe disease), caused by inherited deficiency of acid alpha-glucosidase, is a lysosomal disorder affecting heart and skeletal muscles. A mouse model of this disease was obtained by targeted disruption of the murine acid alpha-glucosidase gene (Gaa) in embryonic stem cells. Homozygous knockout mice (Gaa -/-) lack Gaa mRNA and have a virtually complete acid alpha-glucosidase deficiency. Glycogen-containing lysosomes are detected soon after birth in liver, heart and skeletal muscle cells. By 13 weeks of age, large focal deposits of glycogen have formed. Vacuolar spaces stain positive for acid phosphatase as a sign of lysosomal pathology. Both male and female knockout mice are fertile and can be intercrossed to produce progeny. The first born knockout mice are at present 9 months old. Overt clinical symptoms are still absent, but the heart is typically enlarged and the electrocardiogram is abnormal. The mouse model will help greatly to understand the pathogenic mechanism of GSDII and is a valuable instrument to explore the efficacy of different therapeutic interventions.

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Role of the Surface-Exposed and Copper-Coordinating Histidine in Blue Copper Proteins: The Electron-Transfer and Redox-Coupled Ligand Binding Properties of His117Gly Azurin

et al. 2000

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In many reduced blue copper proteins the C-terminal surface-exposed active-site histidine protonates at low pH and dissociates from the Cu atom. In this state, the proteins exhibit high reduction potentials and low oxidation rates. In contrast, the homologous histidine (117) of azurin does not protonate. This difference has been examined by studying the electrochemical behavior of an azurin mutant in which histidine 117 is replaced by glycine to create a cavity enabling external ligands to enter the protein and coordinate to the Cu. We show that the external ligands influence the electrochemical properties of the copper site, as studied with potentiometric titrations of protein solutions and with fast-scan and low-temperature cyclic voltammetry of protein films adsorbed on graphite electrodes. The reduction potential (E 0′ ) of His117Gly azurin without external ligands is very high, at 670 ( 10 mV, but it decreases upon addition of Clor imidazole. The reduced form has little affinity for these ligands; however, under fast-scan or cryoscopic conditions (-70 °C, 70% methanol) the reduced form of the imidazole complex can be "trapped", and a reversible redox couple is established. The electrochemical kinetics of the trapped state are very fast and similar to those of wild-type (wt) azurin. The reduction potential is ∼60 mV lower than for wt azurin under identical conditions. The dissociation constant K diss of the Cu(I)-imidazole complex lies between 14 and 69 M at 20 °C, while that of the Cu(I)-Clcomplex is estimated to be as high as 10 6 M. These very low affinities show that for wt azurin the covalent link between the imidazole side chain of His117 and the protein framework is crucial for maintaining this side chain as a ligand of the Cu(I) ion.

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Glycogenosis type II (acid maltase deficiency)

et al. 1995

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Glycogen storage disease type II (GSD II/glycogenosis type II/Pompe's disease/acid maltase deficiency) is caused by the deficiency of lysosomal α‐glucosidase resulting in lysosomal accumulation of glycogen. The disease is inherited as an autosomal recessive trait and is clinically heterogeneous. Early and late onset phenotypes are distinguished. Insight in the molecular nature of the lysosomal α‐glucosidase deficiency and the underlying genetic defect has increased significantly during the past decade. This minireview on GSD II was written at the occasion of The International Symposium on Glycolytic and Mitochondrial Defects in Muscle and Nerve, held in Osaka, Japan, July 1994. It is an update of current literature, but also includes original data from the collaborating authors on mutations occurring in the lysosomal α‐glucosidase gene and on prenatal diagnosis by chorionic villus sampling. The genotype–phenotype correlation and the prospects for therapy are addressed. © 1995 John Wiley & Sons, Inc.

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Protein Film Voltammetry of Copper-Containing Nitrite Reductase Reveals Reversible Inactivation

et al. 2007

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The Cu-containing nitrite reductase from Alcaligenes faecalis S-6 catalyzes the one-electron reduction of nitrite to nitric oxide (NO). Electrons enter the enzyme at the so-called type-1 Cu site and are then transferred internally to the catalytic type-2 Cu site. Protein film voltammetry experiments were carried out to obtain detailed information about the catalytic cycle. The homotrimeric structure of the enzyme is reflected in a distribution of the heterogeneous electron-transfer rates around three main values. Otherwise, the properties and the mode of operation of the enzyme when it is adsorbed as a film on a pyrolytic graphite electrode are essentially unchanged compared to those of the free enzyme in solution. It was established that the reduced type-2 site exists in either an active or an inactive conformation with an interconversion rate of approximately 0.1 s(-1). The random sequential mechanism comprises two routes, one in which the type-2 site is reduced first and subsequently binds nitrite, which is then converted into NO, and another in which the oxidized type-2 site binds nitrite and then accepts an electron to produce NO. At high nitrite concentration, the second route prevails and internal electron transfer is rate-limiting. The midpoint potentials of both sites could be established under catalytic conditions. Binding of nitrite to the type-2 site does not affect the midpoint potential of the type-1 site, thereby excluding cooperativity between the two sites.

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