The Proton Transfer Step Catalyzed by Yeast Pyruvate Kinase

Susan‐Resiga, Delia; Nowak, Thomas

doi:10.1074/jbc.m300257200

Cited by 25 publications

(36 citation statements)

References 35 publications

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“…Altogether, these data show that divalent ions are essential for GlcAT-I activity as well as for substrate binding, but do not provide information on the activation mechanism. Kinetic analyses combined with site-directed mutagenesis have been successfully used to assess metal effects in enzyme activation (32,33). We thus initiated kinetic studies of Mn 2ϩ activation of wild-type and mutant GlcAT-I.…”

Section: Discussionmentioning

confidence: 99%

The Functional Glycosyltransferase Signature Sequence of the Human β1,3-Glucuronosyltransferase Is a XDD Motif

Gulberti

Fournel‐Gigleux

Mulliert

et al. 2003

Journal of Biological Chemistry

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The human ␤1,3-glucuronosyltransferase I (GlcAT-I) is the key enzyme responsible for the completion of glycosaminoglycan-protein linkage tetrasaccharide of proteoglycans (GlcA␤1,3Gal␤1,3Gal␤1,4Xyl␤1-O-serine 2؉ were crucial for GlcAT-I function. Altogether, these results indicated that, similarly to the SpsA enzyme, the nucleotide binding site of GlcAT-I contains a XDD motif rather than a DXD motif.

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Section: Discussionmentioning

confidence: 99%

The Functional Glycosyltransferase Signature Sequence of the Human β1,3-Glucuronosyltransferase Is a XDD Motif

Gulberti

Fournel‐Gigleux

Mulliert

et al. 2003

Journal of Biological Chemistry

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“…Each mutant enzyme has different kinetic characteristics. The results led to the conclusion that a molecule of bound water at the active site serves as the proton donor (6). In an effort to characterize further the effect of these mutations at the active site, the interaction between the enzyme-bound divalent activator (Mn 2ϩ ) and the monovalent activator (Tl ϩ ) was investigated in each of the mutants by appropriate NMR studies.…”

Section: Discussionmentioning

confidence: 99%

“…The measurement of 1/T 1M values at 346 MHz for wild type YPK and the T298S mutant enzyme-Tl ϩ -PEP and enzyme-Tl ϩ -PEP-FBP complexes indicates that there is a frequency dependence for 1/T 1M , based on Equation 6 and that the measured values reflect relaxation (Table III). There is no frequency dependence for the 1/pT 2p values for these complexes (Table III).…”

Section: Methodsmentioning

confidence: 99%

“…All three Thr-298 mutants of YPK, T298S, T298C and T298A, showed altered k cat and k cat /K m,PEP values and altered kinetic cooperativity with PEP relative to wild type PK (6). It is possible that these alterations in kinetic parameters of the YPK Thr-298 mutants may, in part, be explained by structural changes at the active site as a result of the single amino acid mutations.…”

mentioning

confidence: 92%

“…1). The role of Thr-298 in the YPK-catalyzed reaction has been addressed by mutation of this residue to serine, alanine (6), and to cysteine. 2 Studies of these mutants suggest that Thr-298 is not the proton donor to the enolate of pyruvate but that enzyme-bound water serves this function.…”

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confidence: 99%

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Monitoring Active Site Alterations upon Mutation of Yeast Pyruvate Kinase Using 205Tl+ NMR

Susan‐Resiga

Nowak

2003

Journal of Biological Chemistry

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Yeast pyruvate kinase (YPK) 1 (EC 2.7.1.4.0) is a tetrameric enzyme of identical subunits with a subunit molecular mass of 54.5 kDa (1). PK is a key regulatory enzyme in glycolysis that catalyzes the nearly irreversible reaction of phosphoenolpyruvate (PEP) and ADP to yield pyruvate and ATP. YPK has an absolute requirement for both monovalent and divalent cations, undergoes homotropic activation by PEP and M 2ϩ , and heterotropic activation by fructose 1,6-bisphosphate (FBP). Potassium is the physiologically important monovalent activator, but several other monovalent cations (Li ϩ , Naϩ , CH 3 -NH 4 ϩ ) can also activate PK (2-4).The refined x-ray structures of the YPK-K ϩ -Mn 2ϩ -phosphoglycolate and YPK-K ϩ -Mn 2ϩ -phosphoglycolate-FBP complexes have been solved at 3 Å resolution (5). Phosphoglycolate is a structural analog of the substrate PEP that lacks the C-3 carbon. From the x-ray data, the active site Thr-298 is in the correct orientation to serve as the proton donor to the C-3 of the enolate of pyruvate, the enzyme-bound intermediate (Fig. 1). The role of Thr-298 in the YPK-catalyzed reaction has been addressed by mutation of this residue to serine, alanine (6), and to cysteine.2 Studies of these mutants suggest that Thr-298 is not the proton donor to the enolate of pyruvate but that enzyme-bound water serves this function. Far-UV CD analysis indicates that none of the mutations cause any significant change in the secondary structure and that wild type and mutant YPK enzymes are folded into a similar, if not identical, structure. Physical and kinetic studies with the Thr-298 mutants of YPK indicate that the single amino acid mutations at the active site can trigger long range effects. These effects were observed at the FBP-binding site, located more than 40 Å away from the active site (5). The Thr-298 residue is about 6.5 Å from the enzyme-bound divalent cation and 8.9 Å from the monovalent cation at the active site ( Fig. 1) (5).All three Thr-298 mutants of YPK, T298S, T298C and T298A, showed altered k cat and k cat /K m,PEP values and altered kinetic cooperativity with PEP relative to wild type PK (6). It is possible that these alterations in kinetic parameters of the YPK Thr-298 mutants may, in part, be explained by structural changes at the active site as a result of the single amino acid mutations. Such alterations may be too subtle to be monitored by methods such as CD and fluorescence spectroscopy, which are sensitive to more gross changes in protein structures.When performing site-directed mutagenesis studies, the possibility of local structural alterations introduced upon mutation tends to be overlooked in the interpretation and assessment of overall properties and behavior of the resulting protein mutants relative to the wild type protein. The ability to address these questions is normally limited by lack of appropriate experimental tools. Yeast PK has an advantage in that it is amenable to such an analysis. Measurement of the internuclear interactions between the mono-and divalent cations, b...

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Acid–Base and Solvation Properties of Metal Enolates Part 2: Transition‐Metal Enolates and Medium Effects

Bastos

2017

Patai's Chemistry of Functional Groups

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The Proton Transfer Step Catalyzed by Yeast Pyruvate Kinase

Cited by 25 publications

References 35 publications

The Functional Glycosyltransferase Signature Sequence of the Human β1,3-Glucuronosyltransferase Is a XDD Motif

The Functional Glycosyltransferase Signature Sequence of the Human β1,3-Glucuronosyltransferase Is a XDD Motif

Monitoring Active Site Alterations upon Mutation of Yeast Pyruvate Kinase Using 205Tl+ NMR

Acid–Base and Solvation Properties of Metal Enolates Part 2: Transition‐Metal Enolates and Medium Effects

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