Your search keyword '"Odili, A."' showing total 5 results

1. Mutational analysis of allosteric activation and inhibition of glucokinase

Author

Carol Buettger, Pan Chen, Jane M. Vanderkooi, Ramakanth Sarabu, Bogumil Zelent, Monique Laberge, Joseph Grimsby, Franz M. Matschinsky, Stella Odili, Dorothy Zelent, Joseph Bass, Deborah Fenner, and Charles A. Stanley

Subjects

Protein Conformation, Mutant, Allosteric regulation, Biology, Biochemistry, Fluorescence, Article, Protein structure, Allosteric Regulation, Glucokinase, Humans, Point Mutation, Enzyme kinetics, Molecular Biology, chemistry.chemical_classification, Activator (genetics), Tryptophan, Cell Biology, Glucose binding, Kinetics, Glucose, Enzyme, chemistry, Carrier Proteins

Abstract

GK (glucokinase) is activated by glucose binding to its substrate site, is inhibited by GKRP (GK regulatory protein) and stimulated by GKAs (GK activator drugs). To explore further the mechanisms of these processes we studied pure recombinant human GK (normal enzyme and a selection of 31 mutants) using steady-state kinetics of the enzyme and TF (tryptophan fluorescence). TF studies of the normal binary GK–glucose complex corroborate recent crystallography studies showing that it exists in a closed conformation greatly different from the open conformation of the ligand-free structure, but indistinguishable from the ternary GK–glucose–GKA complex. GKAs did activate and GKRP did inhibit normal GK, whereas its TF was doubled by glucose saturation. However, the enzyme kinetics, GKRP inhibition, TF enhancement by glucose and responsiveness to GKA of the selected mutants varied greatly. Two predominant response patterns were identified accounting for nearly all mutants: (i) GK mutants with a normal or close to normal response to GKA, normally low basal TF (indicating an open conformation), some variability of kinetic parameters (kcat, glucose S0.5, h and ATP Km), but usually strong GKRP inhibition (13/31); and (ii) GK mutants that are refractory to GKAs, exhibit relatively high basal TF (indicating structural compaction and partial closure), usually show strongly enhanced catalytic activity primarily due to lowering of the glucose S0.5, but with reduced or no GKRP inhibition in most cases (14/31). These results and those of previous studies are best explained by envisioning a common allosteric regulator region with spatially non-overlapping GKRP- and GKA-binding sites.

Published

2011

2. Mutational analysis of allosteric activation and inhibition of glucokinase

Author

Zelent, Bogumil, primary, Odili, Stella, additional, Buettger, Carol, additional, Zelent, Dorothy K., additional, Chen, Pan, additional, Fenner, Deborah, additional, Bass, Joseph, additional, Stanley, Charles, additional, Laberge, Monique, additional, Vanderkooi, Jane M., additional, Sarabu, Ramakanth, additional, Grimsby, Joseph, additional, and Matschinsky, Franz M., additional

Published

2011

3. Sugar binding to recombinant wild-type and mutant glucokinase monitored by kinetic measurement and tryptophan fluorescence

Author

Zelent, Bogumil, primary, Odili, Stella, additional, Buettger, Carol, additional, Shiota, Chiyo, additional, Grimsby, Joseph, additional, Taub, Rebecca, additional, Magnuson, Mark A., additional, Vanderkooi, Jane M., additional, and Matschinsky, Franz M., additional

Published

2008

4. Mutational analysis of allosteric activation and inhibition of glucokinase.

Author

Bogumil Zelent, Stella Odili, Carol Buettger, Dorothy K. Zelent, Pan Chen, Deborah Fenner, Joseph Bass, Charles Stanley, Jane M. Vanderkooi, Ramakanth Sarabu, Joseph Grimsby, and Franz M. Matschinsky

Subjects

*GENETIC mutation, *ALLOSTERIC regulation, *REGULATION of glucokinase, *ENZYME inhibitors, *ENZYME activation, *GLUCOSE

Abstract

GK (glucokinase) is activated by glucose binding to its substrate site, is inhibited by GKRP (GK regulatory protein) and stimulated by GKAs (GK activator drugs). To explore further the mechanisms of these processes we studied pure recombinant human GK (normal enzyme and a selection of 31 mutants) using steady-state kinetics of the enzyme and TF (tryptophan fluorescence). TF studies of the normal binary GK–glucose complex corroborate recent crystallography studies showing that it exists in a closed conformation greatly different from the open conformation of the ligand-free structure, but indistinguishable from the ternary GK–glucose–GKA complex. GKAs did activate and GKRP did inhibit normal GK, whereas its TF was doubled by glucose saturation. However, the enzyme kinetics, GKRP inhibition, TF enhancement by glucose and responsiveness to GKA of the selected mutants varied greatly. Two predominant response patterns were identified accounting for nearly all mutants: (i) GK mutants with a normal or close to normal response to GKA, normally low basal TF (indicating an open conformation), some variability of kinetic parameters (kcat, glucose S0.5, h and ATP Km), but usually strong GKRP inhibition (13/31); and (ii) GK mutants that are refractory to GKAs, exhibit relatively high basal TF (indicating structural compaction and partial closure), usually show strongly enhanced catalytic activity primarily due to lowering of the glucose S0.5, but with reduced or no GKRP inhibition in most cases (14/31). These results and those of previous studies are best explained by envisioning a common allosteric regulator region with spatially non-overlapping GKRP- and GKA-binding sites. [ABSTRACT FROM AUTHOR]

Published

2011

5. Sugar binding to recombinant wild-type and mutant glucokinase monitored by kinetic measurement and tryptophan fluorescence.

Author

Bogumil Zelent, Stella Odili, Carol Buettger, Chiyo Shiota, Joseph Grimsby, Rebecca Taub, Mark A. Magnuson, Jane M. Vanderkooi, and Franz M. Matschinsky

Subjects

*LIGAND binding (Biochemistry), *ENZYME kinetics, *GLUCOKINASE, *TRYPTOPHAN

Abstract

Tryptophan fluorescence was used to study GK (glucokinase), an enzyme that plays a prominent role in glucose homoeostasis which, when inactivated or activated by mutations, causes diabetes mellitus or hypoglycaemia in humans. GK has three tryptophan residues, and binding of D-glucose increases their fluorescence. To assess the contribution of individual tryptophan residues to this effect, we generated GST–GK [GK conjugated to GST (glutathione transferase)] and also pure GK with one, two or three of the tryptophan residues of GK replaced with other amino acids (i.e. W99C, W99R, W167A, W167F, W257F, W99R/W167F, W99R/W257F, W167F/W257F and W99R/W167F/W257F). Enzyme kinetics, binding constants for glucose and several other sugars and fluorescence quantum yields (ϕ) were determined and compared with those of wild-type GK retaining its three tryptophan residues. Replacement of all three tryptophan residues resulted in an enzyme that retained all characteristic features of GK, thereby demonstrating the unique usefulness of tryptophan fluorescence as an indicator of GK conformation. Curves of glucose binding to wild-type and mutant GK or GST–GK were hyperbolic, whereas catalysis of wild-type and most mutants exhibited co-operativity with D-glucose. Binding studies showed the following order of affinities for the enzyme variants: N-acetyl-D-glucosamine>D-glucose>D-mannose>D-mannoheptulose>2-deoxy-D-glucose≫L-glucose. GK activators increased sugar binding of most enzymes, but not of the mutants Y214A/V452A and C252Y. Contributions to the fluorescence increase from Trp99 and Trp167 were large compared with that from Trp257 and are probably based on distinct mechanisms. The average quantum efficiency of tryptophan fluorescence in the basal and glucose-bound state was modified by activating (Y214A/V452A) or inactivating (C213R and C252Y) mutations and was interpreted as a manifestation of distinct conformational states. [ABSTRACT FROM AUTHOR]

Published

2008