Thomas Schnyder scite author profile

Creatine kinase (CK, EC 2.7.3.2), an enzyme important for energy metabolism in cells of high and fluctuating energy requirements, catalyses the reversible transfer of a phosphoryl goup from phosphocreatine to ADP. We have solved the structure of the octameric mitochondrial isoform, Mib-CK, which is located in the intermembrane compartment and along the cristae membranes. Mib-CK consumes ATP produced in the mitochondria for the production of phosphocreatine, which is then exported into the cytosol for fast regeneration of ATP by the cytosolic CK isoforms. The octamer has 422 point-group symmetry, and appears as a cube of side length 93 angstrom with a channel 20 angstrom wide extending along the four-fold axis. Positively charged amino acids at the four-fold faces of the octamer possibly interact with negatively charged mitochondrial membranes. Each monomer consists of a small alpha-helical domain and a large domain containing an eight-stranded antiparallel beta-sheet flanked by seven alpha-helices. The conserved residues of the CK family form a compact cluster that covers the active site between the domains.

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Expression of active octameric chicken cardiac mitochondrial creatine kinase in Escherichia coli

Furter

Kaldis

Furter‐Graves

et al. 1992

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Sarcomeric mitochondrial creatine kinase (Mib-CK) of chicken was expressed in Escherichia coli as a soluble enzyme by using an inducible phage-T7 promoter. Up to one third of the protein in E. coli extracts consisted of soluble recombinant Mib-CK in an enzymically active form. Approx. 20 mg of nearly-homogenous Mib-CK was isolated in a two-step isolation procedure starting with 1 litre of isopropyl beta-D-thiogalactopyranoside-induced E. coli culture, whereas previous attempts to express other CK genes in E. coli have resulted in 20-fold lower yields and inclusion-body formation. Selection of the Mib-CK expression plasmid on media containing kanamycin rather than ampicillin extended the time period of maximal Mib-CK expression. Recombinant Mib-CK displayed an identical N-terminal amino acid sequence, identical Km for phosphocreatine and Vmax. values, the same electrophoretic behaviour and the same immunological cross-reactivity as the native enzyme isolated from chicken heart mitochondria. The recombinant Mib-CK had the same molecular mass as native chicken Mib-CK in m.s. analysis, indicating that post-translational modification of the enzyme in chicken tissue does not occur. As judged by gel-permeation chromatography and electron microscopy, recombinant enzyme formed predominantly octameric oligomers with the same overall structure as the chicken heart enzyme. Furthermore, the enzymes isolated from both sources formed protein crystals of space group P42(1)2, when grown in the absence of ATP, with one Mi-CK octamer per asymmetric unit. The indistinguishable X-ray-diffraction patterns indicate identical structures for the native and recombinant proteins.

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Structure of the mitochondrial creatine kinase octamer: high-resolution shadowing and image averaging of single molecules and formation of linear filaments under specific staining conditions.

Schnyder

Gross

Winkler

et al. 1991

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Abstract. The combination of high-resolution tantalum/tungsten (Ta/W) shadowing at very low specimen temperature (-250°C) under ultrahigh vacuum (<2 x 10 -9 mbar) with circular harmonic image averaging revealed details on the surface structure of mitochondrial creatine kinase (Mi-CK) molecules with a resolution <2.5 rim. Mi-CK octamers exhibit a cross-like surface depression dividing the square shaped projection of 10 × 10 nm into four equally sized subdomains, which correspond to the four dimers forming the octameric Mi-CK molecule. By a combination of positive staining (with uranyl acetate) and heavy metal shadowing, internal structures as well as the surface relief of Mi-CK were visualized at the same time at high resolution. Computational image analysis revealed only a single projection class of molecules, but the ability of Mi-CK to form linear filaments, as well as geometrical considerations concerning the formation of octamers by four equal, asymmetric dimers, suggest the existence of at least two distinct faces on the molecule. By image processing of Mi-CK filaments a side view of the octamer differing from the top-bottom projections of single molecules became evident showing a funnel-like access each form the top and bottom of the octamer connected by a central channel. The general structure of the Mi-CK octamer described here is relevant to the localization of the molecule at the inner-outer mitochondrial contact sites and to the function of Mi-CK as an "energy channeling" molecule.

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Crystallization of Mitochondrial Creatine Kinase on Negatively Charged Lipid Layers

Schnyder

Cyrklaff

Fuchs

et al. 1994

Journal of Structural Biology

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Mitochondrial creatine kinase from cardiac muscle and brain are two distinct isoenzymes but both form octameric molecules.

Schlegel¹,

Wyss²,

Schürch³

et al. 1988

Journal of Biological Chemistry

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Thomas Schnyder

Structure of mitochondrial creatine kinase

Expression of active octameric chicken cardiac mitochondrial creatine kinase in Escherichia coli

Structure of the mitochondrial creatine kinase octamer: high-resolution shadowing and image averaging of single molecules and formation of linear filaments under specific staining conditions.

Crystallization of Mitochondrial Creatine Kinase on Negatively Charged Lipid Layers

Mitochondrial creatine kinase from cardiac muscle and brain are two distinct isoenzymes but both form octameric molecules.

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