Browsing by Subject "allostery"
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Item A Structural and Kinetic Study into the Role of the Quaternary Shift in Bacillus stearothermophilus Phosphofructokinase(2011-10-21) Mosser, Rockann ElizabethBacillus stearothermophilus phosphofructokinase (BsPFK) is a homotetramer that is allosterically inhibited by phosphoenolpyruvate (PEP), which binds along one dimer-dimer interface. The substrate, fructose-6-phosphate (F6P), binds along the other dimer-dimer interface. The different functional forms BsPFK can take when in the presence of F6P and PEP can be described by the following diproportionation equilibrium: XE + EA <--> XEA + E where XE is the enzyme bound to PEP, EA is the enzyme bound to F6P, E represents the apo enzyme, and XEA is the ternary complex formed when both substrate and inhibitor are bound. Currently in the Protein Data Bank (PDB) there are two relevant forms of wild-type BsPFK, the EA form and the X'E form, which represents the enzyme bound to the PEP analog, phosphoglycolate (PGA). When comparing the EA and the X'E structures, a 7? rotation about the substrate-binding interface is observed and is termed the quaternary shift. The current study uses methyl TROSY NMR to examine the different liganded states of BsPFK, and for the first time structural data for the XEA species is shown. In addition, crystallography was used to obtain the first apo structure of BsPFK. To distinguish between changes associated with the quaternary shift and those associated with the intra-subunit tertiary changes, the variant D12A BsPFK was studied using kinetics, crystallography, and NMR. Crystal structures of apo and PEP bound forms of D12A BsPFK both indicate a shifted structure similar to the X'E form of wild-type. Kinetic studies of D12A BsPFK, when compared to wild-type, show a 50-fold diminished F6P binding affinity, 100-fold enhanced binding affinity, and a similar coupling constant. A conserved hydrogen bond between D12 and T156 takes place across the substrate binding interface in the EA form of BsPFK. The variant T156A BsPFK shows similar binding, coupling, and structural characteristics to D12A BsPFK. PEP still inhibits these variants of BsPFK despite the fact that the enzymes are in the quaternary shifted position prior to PEP binding. Therefore the quaternary shift of BsPFK primarily perturbs ligand binding but does not directly contribute to heterotropic allosteric inhibition.Item Characterization of the Allosteric Properties of Thermus thermophilus Phosphofructokinase and the Sources of Strong Inhibitor Binding Affinity and Weak Inhibitory Response(2012-10-19) Shubina-McGresham, MariaCharacterization of allosteric properties of phosphofructokinase from the extreme thermophile Thermus thermophilus (TtPFK) using thermodynamic linkage analysis revealed several peculiarities. Inhibition and activation of Fru-6-P binding by the allosteric effectors phosphoenolpyruvate (PEP) and MgADP are entropically-driven in TtPFK. It is also curious that PEP binding affinity is unusually strong in TtPFK when compared to PFKs from Escherichia coli, Bacillus stearothermophilus, and Lactobacillus delbrueckii, while the magnitude of the allosteric inhibition by PEP is much smaller in TtPFK. In an effort to understand the source of weak inhibition, a putative network of residues between the allosteric site and the nearest active site was identified from the three-dimensional structures of BsPFK. Three of the residues in this network, D59, T158, and H215, are not conserved in TtPFK, and, due to their nature (N59, A158, S215), are unlikely to be involved in the same non-covalent interactions seen in BsPFK. The triple chimeric substitution N59D/A158T/S215H, results in a 2.5 kcal mol-1 increase in the coupling free energy, suggesting that the region containing these residues may be important for propagation of inhibitory response. The individual substitutions at each position resulted in an increase in the coupling free energy, and the double substitutions displayed additivity of these changes. The chimeric substitution made at N59 suggests that the polar nature of the asparagine at position 59 is key for the enhanced binding of PEP. The non-conserved R55 was found to be particularly important for the enhanced binding of PEP in TtPFK, as chimeric substitutions R55G and R55E resulted in a 3.5 kcal mol-1 and 4.5 kcal mol-1 decrease in the binding affinity for PEP, respectively. Our results also confirm the observations previously made in PFKs from E. coli and B. stearothermophilus, that the ability of the effector to bind is independent of its ability to produce allosteric response. We show that several substitutions result in a decrease in binding affinity of PEP to TtPFK, while dramatically enhancing its ability to inhibit (N59D, R55G, R55E). Similarly, some substitutions, like S215H and A158T show an enhanced inhibition by PEP, while having no effect on its binding affinity.Item Illuminating the Heterotropic Communication of the Pair-wise Interactions in Phosphofructokinase from Bacillus stearothermophilus(2012-10-17) Perez, StephanieThe number of allosteric sites and active sites in phosphofructokinase from Bacillus stearothermophilus create an intricate network of communication within the enzyme. With thermodynamic linkage analysis, the overall allosteric communication can be quantified. This value, however, represents an average contribution for all the interactions involved. The recent development of a hybrid strategy has allowed for the quantification of single interactions, both heterotropic and homotropic. Focusing on the heterotropic interactions whose inhibition is entropy-driven, residues and regions within the enzyme can now be identified to further characterize each specific interaction using the hybrid strategy. Among the many components of entropy, the hybrid strategy has now allowed for the strategic placement of a reporter of side chain dynamics to identify conformational differences between the four ligand bound enzyme species of a single heterotropic interaction. In this study, a combination of these approaches was used in the methodology including constructing hybrids to isolate a single heterotropic interaction along with single tryptophan reporter. Site directed mutagenesis combined with the hybrid strategy was also implemented to directly assess the role of a single residue in the communication path of a single interaction. The region surrounding the allosteric site with the nearest active site has been implicated to be significant in transmitting the allosteric signal. In addition two single residues, T158 and D59, within this region have been identified to potentially contribute to the inhibition of this same interaction. An additional residue, G184, located outside this local region has also been identified as possibly having a significant role in the transmission of the inhibitory signal of a unique heterotropic interaction. The implications of this study have led to the initial identification of residues involved in the 22A route of allosteric communication of a single active site and allosteric site. This allosteric communication occurs to allow the enzyme to compensate for the binding of both ligands. With the location of these residues implicated to be involved in the communication of this isolated interaction, this compensation is not contained within a confined region but is however felt throughout the single subunit.