Kientic Study of Yeast Hexokinase. 2. Analysis of the Progress Curve of the Reaction

1. 2-Deoxy-2-fluoro-d-glucose, 2-deoxy-2-fluoro-d-mannose and 2-deoxy-2,2-difluoro-d-arabino-hexose are good substrates for yeast hexokinase. 2. 3-Deoxy-3-fluoro-d-glucose and 4-deoxy-4-fluoro-d-glucose are poor substrates and have very similar Km values (8×10−2m). 3. Neither α- nor β-d-glucopyranosyl fluoride is a substrate or inhibitor. 4. Studies with 2-chloro-2-deoxy- and 2-O-methyl derivatives of d-glucose and d-mannose have revealed that little chemical modification is possible at position 2 without substantial loss in substrate binding. 5. The variation in the value of Km for the d-hexose derivatives was associated with a corresponding change in the value of Km for MgATP2− showing that the binding of MgATP2− is modified by the binding of the sugar.

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Dissociation and catalysis in yeast hexokinase A.

Biochemical Journal ◽

10.1042/bj1550661 ◽

1976 ◽

Vol 155 (3) ◽

pp. 661-667 ◽

Cited By ~ 7

Author(s):

D C Williams ◽

J G Jones

Keyword(s):

Catalytic Activity ◽

Steady State ◽

Ternary Complex ◽

Specific Activity ◽

Temperature Dependent ◽

Gradual Decline ◽

Experimental Conditions ◽

Progress Curve ◽

Catalytically Active ◽

Yeast Hexokinase

1. The specific activity of yeast hexokinase A depends on the concentration of the protein in the solution being assayed. When a solution containing 13.5 mg of hexokinase A/ml is diluted 10-100-fold at various values of pH and temperature, there is a gradual decline in the specific activity of the enzyme until an equilibrium value is reached, which varies with the chosen experimental conditions. 2. The catalytic activity lost when hexokinase A (1 mg/ml) is incubated at 30degreesC is recovered by lowering the temperature to 25degreesC. 3. These concentration- and temperature-dependent phenomena are consistent with the existence of a monomer-dimer equilibrium in which the dimer alone is the catalytic form of the enzyme. 4. Glucose alone prevents the decline in specific activity of hexokinase A after dilution, but it does not re-activate dilute solutions solutions of the enzyme. It is concluded that glucose binds to both the dimer and the monomer and prevents both association and dissociation. 5. The progress curve describing the phosphorylation of glucose catalysed by hexokinase A does not attain a steady state. It is possible that dissociation of catalytically active dimers in a ternary complex with glucose and ATP (or glucose 6-phosphate and ADP) could explain the non-linearity of this progress curve.

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Engineering Yeast Hexokinase 2 for Improved Tolerance Toward Xylose-Induced Inactivation

PLoS ONE ◽

10.1371/journal.pone.0075055 ◽

2013 ◽

Vol 8 (9) ◽

pp. e75055 ◽

Cited By ~ 13

Author(s):

Basti Bergdahl ◽

Anders G. Sandström ◽

Celina Borgström ◽

Tarinee Boonyawan ◽

Ed W. J. van Niel ◽

...

Keyword(s):

Hexokinase 2 ◽

Yeast Hexokinase

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Faculty Opinions recommendation of Functional domains of yeast hexokinase 2.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.6591956.6727054 ◽

2010 ◽

Author(s):

Carlos Gancedo

Keyword(s):

Functional Domains ◽

Hexokinase 2 ◽

Yeast Hexokinase

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Functional domains of yeast hexokinase 2

Biochemical Journal ◽

10.1042/bj20100663 ◽

2010 ◽

Vol 432 (1) ◽

pp. 181-190 ◽

Cited By ~ 34

Author(s):

Rafael Peláez ◽

Pilar Herrero ◽

Fernando Moreno

Keyword(s):

Amino Acids ◽

Glucose Repression ◽

Glycolytic Enzyme ◽

Regulatory Function ◽

Wild Type ◽

Hexokinase 2 ◽

Multifunctional Protein ◽

Repressor Complex ◽

Yeast Hexokinase

Hkx2 (hexokinase 2) from Saccharomyces cerevisiae was one of the first metabolic enzymes described as a multifunctional protein. Hxk2 has a double subcellular localization: it functions as a glycolytic enzyme in the cytoplasm and as a regulator of gene transcription of several Mig1-regulated genes in the nucleus. To get more insights into the structure–function relationships of the Hxk2 protein, we followed two different approaches. In the first, we deleted the last eight amino acids of Hxk2 and replaced Ser304 with phenylalanine to generate Hxk2wca. Analysis of this mutant demonstrated that these domains play an essential role in the catalytic activity of yeast Hxk2, but has no effect on the regulatory function of this protein. In the second, we analysed whether amino acids from Lys6 to Met15 of Hxk2 (Hxk2wrf) are essential for the regulatory role of Hxk2 and whether there is an effect on the hexose kinase activity of this protein. In the present paper, we report that the Hxk2wca mutant protein interacts with the Mig1 transcriptional repressor and the Snf1 protein kinase in the nucleus at the level of the SUC2–Mig1 repressor complex. We have demonstrated that Hxk2wca maintained full regulatory function because the glucose-repression signalling of the wild-type machinery is maintained. We also report that the Hxk2wrf mutant allele is incapable of glucose repression signalling because it does not interact with Mig1 at the level of the SUC2–Mig1 repressor complex. The two mutants, Hxk2wca and Hxk2wrf retain single functions, as a transcriptional factor or as an enzyme with hexose-phosphorylating activity, but have lost the original bifunctionality of Hxk2.

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