Jussi Kankare scite author profile

Using site-directed mutagenesis, we have completed replacing all 17 putative active site residues of Escherichia coli inorganic pyrophosphatase (PPase). We report here the production of 11 new variant proteins and their initial characterization, including thermostability, hydrophobicity, oligomeric structure, and specific activity at pH 8. Studies of the pH-rate profiles of 12 variants containing substitutions for potentially essential residues showed that the effect of the mutation was always to increase the pKa of a basic group essential for both substrate binding and catalysis by 1-3 pH units. The D70E variant had the lowest activity at all pHs; the K29R, R43K, and K142R variants also had low kcat/Km values. The principal effect seen in the other variant proteins was higher and sharper pH optima; their pH-independent kcat and kcat/Km values changed at most by a factor of 8. Our results suggest that the most likely candidate for the essential basic group affected by all mutations in the active site is a hydroxide ion stabilized by coordination to the essential Mg2+ ions. Analyzing our results using the structure recently obtained for E. coli PPase [Kankare et al. (1994) Protein Eng. 7, 823-830] led us to identify a group of residues, centered around Asp70 and including Tyr55, Asp65, Asp67, Asp102, and Lys104, that we believe binds the magnesium ions that are critical for the activity, possibly by stabilizing the essential hydroxide. Others, including Lys29, Arg43, and Lys142, are more spread out and more positively charged. They appear to be involved in binding substrate and product. Tyr55 is also a key part of the hydrophobic core of E. coli PPase; when it or residues that interact with it are conservatively mutated, there are changes in the overall structure of the enzyme as assayed by thermostability, hydrophobicity, or oligomeric structure.

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The structure of E.coli soluble inorganic pyrophosphatase at 2.7 Å resolution

Kankare

Neal²,

Salminen

et al. 1994

Protein Eng Des Sel

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The structure of E.coli soluble inorganic pyrophosphatase has been refined at 2.7 A resolution to an R-factor of 20.9%. The overall fold of the molecule is essentially the same as yeast pyrophosphatase, except that yeast pyrophosphatase is longer at both the N- and C-termini. Escherichia coli pyrophosphatase is a mixed alpha + beta protein with a complicated topology. The active site cavity, which is also very similar to the yeast enzyme, is formed by seven beta-strands and an alpha-helix and has a rather asymmetric distribution of charged residues. Our structure-based alignment extends and improves upon earlier sequence alignment studies; it shows that probably no more than 14, not 15-17 charged and polar residues are part of the conserved enzyme mechanism of pyrophosphatases. Six of these conserved residues, at the bottom of the active site cavity, form a tight group centred on Asp70 and probably bind the two essential Mg2+ ions. The others, more spreadout and more positively charged, presumably bind substrate. Escherichia coli pyrophosphatase has an extra aspartate residue in the active site cavity, which may explain why the two enzymes bind divalent cation differently. Based on the structure, we have identified a sequence motif that seems to occur only in soluble inorganic pyrophosphatases.

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Weight-Bearing CT Imaging of the Lower Extremity

Tuominen¹,

Kankare²,

Koskinen³

et al. 2013

American Journal of Roentgenology

121

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Crystallographic Identification of Metal-Binding Sites in Escherichia coli Inorganic Pyrophosphatase^,

et al. 1996

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We report refined crystal structures of the hexameric soluble inorganic pyrophosphatase from Escherichia coli (E-PPase) to R-factors of 18.3% and 17.1% at 2.2 and 2.3 angstroms, respectively. Both structures contain two independent monomers in the asymmetric unit of an R32 cell. The difference between the structures is that the latter contains 1.5 Mg2+ ions per monomer. One metal ion binds to the "tight" metal-binding site identified by equilibrium dialysis studies, and is coordinated to Asp65, Asp70, and Asp102. The other metal ion, shared between two monomers at a hitherto unidentified metal-binding site in the dyad interface between trimers, is coordinated through water molecules to Asp26s and Asn24s from two monomers. The hexamers with metal bound to them are more tightly associated than the ones without metal bound to them. Combined with our other mechanistic and structural data, the results suggest that, at high metal concentrations, E-PPase may bind at least 4.5 metals per monomer: two in the active site before binding substrate, two with substrate, and 0.5 in the dyad interface. Glu20 interacts via a water molecule with Asp70 and appears in the related yeast PPase structure (Heikinheimo, manuscript in preparation) to be involved in binding the second metal ion. Magnesium ion therefore stabilizes the hexamer form through both direct and indirect effects. The direct effect is by tighter association at the subunit interface; the indirect effect occurs because magnesium stabilizes the correct conformation of the loop between Glu20 and Ile32, a loop involved a trimer-trimmer interactions. Our results thus provide a structural explanation for the solution studies that show that the E20D variant is partially hexameric and that the hexamer form can be stabilized by binding magnesium ion.

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The biomechanics of the first metatarsal bone in hallux valgus: A preliminary study utilizing a weight bearing extremity CT

Collan

Kankare

Mattila

2013

Foot and Ankle Surgery

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Jussi Kankare

Structure and function analysis of Escherichia coli inorganic pyrophosphatase: is a hydroxide ion the key to catalysis?

The structure of E.coli soluble inorganic pyrophosphatase at 2.7 Å resolution

Weight-Bearing CT Imaging of the Lower Extremity

Crystallographic Identification of Metal-Binding Sites in Escherichia coli Inorganic Pyrophosphatase^,

The biomechanics of the first metatarsal bone in hallux valgus: A preliminary study utilizing a weight bearing extremity CT

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Jussi Kankare

Structure and function analysis of Escherichia coli inorganic pyrophosphatase: is a hydroxide ion the key to catalysis?

The structure of E.coli soluble inorganic pyrophosphatase at 2.7 Å resolution

Weight-Bearing CT Imaging of the Lower Extremity

Crystallographic Identification of Metal-Binding Sites in Escherichia coli Inorganic Pyrophosphatase,

The biomechanics of the first metatarsal bone in hallux valgus: A preliminary study utilizing a weight bearing extremity CT

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Product

Resources

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Crystallographic Identification of Metal-Binding Sites in Escherichia coli Inorganic Pyrophosphatase^,