Aron W. Fenton

Disentangling the web of allosteric communication in a homotetramer: heterotropic inhibition in phosphofructokinase from Escherichia coli.

This study quantifies the contribution of each of the four unique inhibiting heterotropic interactions between the allosteric inhibitor, phosphoenolpyruvate (PEP), and the substrate, fructose 6-phosphate (Fru-6-P), in phosphofructokinase from Escherichia coli (EcPFK). The unique heterotropic interactions, previously labeled by the distances between ligand binding sites, were isolated independently by constructing hybrid tetramers. Of the four unique heterotropic PEP-Fru-6-P interactions, the 45 A interaction contributed 25%, the 30 A interaction contributed 31%, and the 23 A interaction contributed 42% of the total PEP inhibition. The 33 A interaction actually causes a small activation of Fru-6-P binding by PEP and therefore contributed -8% of the total observed PEP inhibition. The pattern of relative contribution to PEP inhibition from each interaction in EcPFK does not follow the same pattern seen in MgADP activation of EcPFK. This observation supports the conclusion that although PEP and MgADP bind to the same site, they do not use the same communication pathways to influence the active site. The pattern of relative contribution describing PEP inhibition observed in this study also does not follow the pattern determined for PEP inhibition in phosphofructokinase from Bacillus stearothermophilus, suggesting that these two highly homologous isoforms are not inhibited in the same manner by PEP.

HDXFinder: automated analysis and data reporting of deuterium/hydrogen exchange mass spectrometry.

Hydrogen/deuterium exchange in combination with mass spectrometry (H/D MS) is a sensitive technique for detection of changes in protein conformation and dynamics. However, wide application of H/D MS has been hindered, in part, by the lack of computational tools necessary for efficient analysis of the large data sets associated with this technique. We report a novel web-based application for automatic analysis of H/D MS experimental data. This application relies on the high resolution of mass spectrometers to extract all isotopic envelopes before correlating these envelopes with individual peptides. Although a fully automatic analysis is possible, a variety of graphical tools are included to aid in the verification of correlations and rankings of the isotopic peptide envelopes. As a demonstration, the rate constants for H/D exchange of peptides from rabbit muscle pyruvate kinase are mapped onto the structure of this protein.

The pH dependence of the allosteric response of human liver pyruvate kinase to fructose-1,6-bisphosphate, ATP, and alanine

The allosteric regulation of human liver pyruvate kinase (hL-PYK) by fructose-1,6-bisphosphate (Fru-1,6-BP; activator), ATP (inhibitor) and alanine (Ala; inhibitor) was monitored over a pH range from 6.5 to 8.0 at 37 degrees C. As a function of increasing pH, hL-PYKs affinity for the substrate phosphoenolpyruvate (PEP), and for Fru-1,6-BP decreases, while affinities for ATP and alanine slightly increases. At pH 6.5, Fru-1,6-BP and ATP elicit only small allosteric impacts on PEP affinity. As pH increases, Fru-1,6-BP and ATP elicit greater allosteric responses, but the response to alanine is relatively constant. Since the magnitudes of the allosteric coupling for ATP and for alanine inhibition are different and the pH dependences of these magnitudes are not similar, these inhibitors likely elicit their responses using different molecular mechanisms. In addition, our results fail to support a general correlation between pH dependent changes in effector affinity and pH dependent changes in the corresponding allosteric response.

THE IMPACT OF IONS ON ALLOSTERIC FUNCTIONS IN HUMAN LIVER PYRUVATE KINASE

Experimental designs used to monitor the magnitude of an allosteric response can greatly influence observed values. We report here the impact of buffer, monovalent cation, divalent cation, and anion on the magnitude of the allosteric regulation of the affinity of human liver pyruvate kinase (hL-PYK) for substrate, phosphoenolpyruvate (PEP). The magnitudes of the allosteric activation by fructose-1,6-bisphosphate (Fru-1,6-BP) and the allosteric inhibition by alanine are independent of most, but not all buffers tested. However, these magnitudes are dependent on whether Mg(2+) or Mn(2+) is included as the divalent cation. In the presence of Mn(2+), any change in K(app-PEP) caused by Fru-1,6-BP is minimal. hL-PYK activity does not appear to require monovalent cation. Monovalent cation binding in the active site impacts PEP affinity with minimum influence on the magnitude of allosteric coupling. However, Na(+) and Li(+) reduce the magnitude of the allosteric response to Fru-1,6-BP, likely due to mechanisms outside of the active site. Which anion is used to maintain a constant monovalent cation concentration also influences the magnitude of the allosteric response. The value of determining the impact of ions on allosteric function can be appreciated by considering that representative structures used in comparative studies have often been determined using protein crystals grown in diverse buffer and salt conditions.

An activating interaction between the unphosphorylated n-terminus of human liver pyruvate kinase and the main body of the protein is interrupted by phosphorylation.

The initial 26 amino acids of human liver pyruvate kinase (L-PYK) are not present/observed in the crystal structure. This region includes Ser12, the site of hormone-dependent phosphorylation. Truncating the N-terminus of L-PYK mimics the effects of phosphorylation by causing a decrease in apparent phosphoenolpyruvate (PEP) affinity. An N-terminus truncation series was used to map the minimum number of residues that could be removed to result in the decrease in apparent PEP affinity. Results are consistent with a mechanism by which phosphorylation at Ser12 interrupts an activating interaction of N-terminal residues (including those at positions 7-10) with the main body of the protein, as a means of inhibiting substrate affinity.

Identification of Regions of Rabbit Muscle Pyruvate Kinase Important for Allosteric Regulation by Phenylalanine, Detected by H/D Exchange Mass Spectrometry

Mass spectrometry has been used to determine the number of exchangeable backbone amide protons and the associated rate constants that are altered when rabbit muscle pyruvate kinase (rM1-PYK) binds either the allosteric inhibitor (phenylalanine) or a nonallosteric analogue of the inhibitor. Alanine is used as the nonallosteric analogue because it binds competitively with phenylalanine but elicits a negligible allosteric inhibition, i.e., a negligible reduction in the affinity of rM1-PYK for the substrate, phosphoenolpyruvate. This experimental design is expected to distinguish changes in the protein caused by effector binding (i.e., those changes common upon the addition of alanine vs phenylalanine) from changes associated with allosteric regulation (i.e., those elicited by the addition of phenylalanine binding, but not alanine binding). High-quality peptic fragments covering 98% of the protein were identified. Changes in both the number of exchangeable protons per peptide and in the rate constant associated with exchange highlight regions of the protein with allosteric roles. The set of allosterically relevant peptides identified by this technique includes residues previously identified by mutagenesis to have roles in allosteric regulation by phenylalanine.

The pyruvate kinase model system, a cautionary tale for the use of osmolyte perturbations to support conformational equilibria in allostery

In the study of rabbit muscle pyruvate kinase (M1‐PYK), proline has previously been used as an osmolyte in an attempt to determine a role for preexisting conformational equilibria in allosteric regulation. In this context, osmolytes are small molecules assumed to have no direct interaction with the protein. In contrast to prolines proposed role as an osmolyte, the structure of M1PYK‐Mn‐pyruvate‐proline complex reported herein demonstrates that proline binds specifically to the allosteric site of M1‐PYK. Therefore, this amino acid is an allosteric effector rather than a benign osmolyte. Other compounds often used as osmolytes (polyethyleneglycol and glycerol) are also present in the structure, suggesting an interaction with the protein that would, in turn, prevent the usefulness of these compounds in the study of this and most likely other proteins. These findings highlight the need to verify that compounds used as osmolytes to perturb preexisting conformational equilibrium do not directly interact with the protein, a consideration not commonly addressed in the past.

Changes in small-angle X-ray scattering parameters observed upon binding of ligand to rabbit muscle pyruvate kinase are not correlated with allosteric transitions.

Protein fluorescence and small-angle X-ray scattering (SAXS) have been used to monitor effector affinity and conformational changes previously associated with allosteric regulation in rabbit muscle pyruvate kinase (M(1)-PYK). In the absence of substrate [phosphoenolpyruvate (PEP)], SAXS-monitored conformational changes in M(1)-PYK elicited by the binding of phenylalanine (an allosteric inhibitor that reduces the affinity of M(1)-PYK for PEP) are similar to those observed upon binding of alanine or 2-aminobutyric acid. Under our assay conditions, these small amino acids bind to the protein but elicit a minimal change in the affinity of the protein for PEP. Therefore, if changes in scattering signatures represent cleft closure via domain rotation as previously interpreted, we can conclude that these motions are not sufficient to elicit allosteric inhibition. Additionally, although PEP has similar affinities for the free enzyme and the M(1)-PYK-small amino acid complexes (i.e., the small amino acids have minimal allosteric effects), PEP binding elicits different changes in the SAXS signature of the free enzyme versus the M(1)-PYK-small amino acid complexes.

Distinguishing the chemical moiety of phosphoenolpyruvate that contributes to allostery in muscle pyruvate kinase.

A series of substrate analogues has been used to determine which chemical moieties of the substrate phosphoenolpyruvate (PEP) contribute to the allosteric inhibition of rabbit muscle pyruvate kinase by phenylalanine. Replacing the carboxyl group of the substrate with a methyl alcohol or removing the phosphate altogether greatly reduces substrate affinity. However, removal of the carboxyl group is the only modification tested that removes the ability to allosterically reduce the level of Phe binding. From this, it can be concluded that the carboxyl group of PEP is responsible for energetic coupling with Phe binding in the allosteric sites.

Whole-protein alanine-scanning mutagenesis of allostery: A large percentage of a protein can contribute to mechanism

Many studies of allosteric mechanisms use limited numbers of mutations to test whether residues play “key” roles. However, if a large percentage of the protein contributes to allosteric function, mutating any residue would have a high probability of modifying allostery. Thus, a predicted mechanism that is dependent on only a few residues could erroneously appear to be supported. We used whole‐protein alanine‐scanning mutagenesis to determine which amino acid sidechains of human liver pyruvate kinase (hL‐PYK; approved symbol PKLR) contribute to regulation by fructose‐1,6‐bisphosphate (Fru‐1,6‐BP; activator) and alanine (inhibitor). Each nonalanine/nonglycine residue of hL‐PYK was mutated to alanine to generate 431 mutant proteins. Allosteric functions in active proteins were quantified by following substrate affinity over a concentration range of effectors. Results show that different residues contribute to the two allosteric functions. Only a small fraction of mutated residues perturbed inhibition by alanine. In contrast, a large percentage of mutated residues influenced activation by Fru‐1,6‐BP; inhibition by alanine is not simply the reverse of activation by Fru‐1,6‐BP. Moreover, the results show that Fru‐1,6‐BP activation would be extremely difficult to elucidate using a limited number of mutations. Additionally, this large mutational data set will be useful to train and test computational algorithms aiming to predict allosteric mechanisms.