Showing papers on "Conformational change published in 2008"

Dynamic energy landscape view of coupled binding and protein conformational change: Induced-fit versus population-shift mechanisms

Abstract: Allostery, the coupling between ligand binding and protein conformational change, is the heart of biological network and it has often been explained by two representative models, the induced-fit and the population-shift models. Here, we clarified for what systems one model fits better than the other by performing molecular simulations of coupled binding and conformational change. Based on the dynamic energy landscape view, we developed an implicit ligand-binding model combined with the double-basin Hamiltonian that describes conformational change. From model simulations performed for a broad range of parameters, we uncovered that each of the two models has its own range of applicability, stronger and longer-ranged interaction between ligand and protein favors the induced-fit model, and weaker and shorter-ranged interaction leads to the population-shift model. We further postulate that the protein binding to small ligand tends to proceed via the population-shift model, whereas the protein docking to macromolecules such as DNA tends to fit the induced-fit model.

Conformational cross-talk between alpha2A-adrenergic and mu-opioid receptors controls cell signaling.

Abstract: Morphine, a powerful analgesic, and norepinephrine, the principal neurotransmitter of sympathetic nerves, exert major inhibitory effects on both peripheral and brain neurons by activating distinct cell-surface G protein-coupled receptors-the mu-opioid receptor (MOR) and alpha2A-adrenergic receptor (alpha2A-AR), respectively. These receptors, either singly or as a heterodimer, activate common signal transduction pathways mediated through the inhibitory G proteins (G(i) and G(o)). Using fluorescence resonance energy transfer microscopy, we show that in the heterodimer, the MOR and alpha2A-AR communicate with each other through a cross-conformational switch that permits direct inhibition of one receptor by the other with subsecond kinetics. We discovered that morphine binding to the MOR triggers a conformational change in the norepinephrine-occupied alpha2A-AR that inhibits its signaling to G(i) and the downstream MAP kinase cascade. These data highlight a new mechanism in signal transduction whereby a G protein-coupled receptor heterodimer mediates conformational changes that propagate from one receptor to the other and cause the second receptor's rapid inactivation.

Insights into protein flexibility: The relationship between normal modes and conformational change upon protein-protein docking

Abstract: Understanding protein interactions has broad implications for the mechanism of recognition, protein design, and assigning putative functions to uncharacterized proteins. Studying protein flexibility is a key component in the challenge of describing protein interactions. In this work, we characterize the observed conformational change for a set of 20 proteins that undergo large conformational change upon association (>2 A Cα RMSD) and ask what features of the motion are successfully reproduced by the normal modes of the system. We demonstrate that normal modes can be used to identify mobile regions and, in some proteins, to reproduce the direction of conformational change. In 35% of the proteins studied, a single low-frequency normal mode was found that describes well the direction of the observed conformational change. Finally, we find that for a set of 134 proteins from a docking benchmark that the characteristic frequencies of normal modes can be used to predict reliably the extent of observed conformational change. We discuss the implications of the results for the mechanics of protein recognition.

STIM1–Orai1 interactions and Orai1 conformational changes revealed by live-cell FRET microscopy

Abstract: Ca2+ entry through store-operated Ca2+ release-activated Ca2+ (CRAC) channels initiates key functions such as gene expression and exocytosis of inflammatory mediators. Activation of CRAC channels by store depletion involves the redistribution of the ER Ca2+ sensor, stromal interaction molecule 1 (STIM1), to peripheral sites where it co-clusters with the CRAC channel subunit, Orai1. However, how STIM1 communicates with the CRAC channel and initiates the subsequent events culminating in channel opening is unclear. Here, we show that redistribution of STIM1 and Orai1 occurs in parallel with a pronounced increase in fluorescence resonance energy transfer (FRET) between STIM1 and Orai1, supporting the idea that activation of CRAC channels occurs through physical interactions with STIM1. Co-expression of Orai1–CFP and Orai1–YFP results in a high degree of FRET in resting cells, indicating that Orai1 exists as a multimer. However, store depletion triggers molecular rearrangements in Orai1 resulting in a decline in Orai1–Orai1 FRET. The decline in Orai1–Orai1 FRET is not seen in the absence of STIM1 co-expression and is abolished in Orai1 mutants with impaired STIM1 interaction. Both the STIM1–Orai1 interaction as well as the molecular rearrangements in Orai1 are altered by two powerful modulators of CRAC channel activity: extracellular Ca2+ and 2-APB. These studies identify a STIM1-dependent conformational change in Orai1 during the activation of CRAC channels and reveal that STIM1–Orai1 interaction and the downstream Orai1 conformational change can be independently modulated to fine-tune CRAC channel activity.

Interaction of gold nanoparticles with protein: A spectroscopic study to monitor protein conformational changes

Abstract: Gold nanoparticles (GNPs) conjugated with biomolecules are promising building blocks for assembly into nanostructured functional materials for developing biomarker platforms because of their size dependent optical and electrical properties. Biocompatible GNPs were synthesized using glutamic acid as a reducing agent and the interaction between bovine serum albumin (BSA) and GNPs was investigated using fluorescence and circular dichroism (CD) spectroscopies. The binding constant (Kb) of protein (BSA) to GNPs was determined by measuring the quenching of the fluorescence intensity of tryptophan residues of the protein molecules after conjugation. The conformational change in BSA at its native form after conjugation with GNPs confirmed that protein undergoes a more flexible conformational state on the boundary surface of GNPs after bioconjugation. The CD studies further showed a decrease in the α-helical content after conjugation. The results confirmed that the change in conformation was larger at higher conce...

Spatial and Temporal Regulation of Focal Adhesion Kinase Activity in Living Cells

Abstract: Focal adhesion kinase (FAK) is an essential kinase that regulates developmental processes and functions in the pathology of human disease. An intramolecular autoinhibitory interaction between the FERM and catalytic domains is a major mechanism of regulation. Based upon structural studies, a fluorescence resonance energy transfer (FRET)-based FAK biosensor that discriminates between autoinhibited and active conformations of the kinase was developed. This biosensor was used to probe FAK conformational change in live cells and the mechanism of regulation. The biosensor demonstrates directly that FAK undergoes conformational change in vivo in response to activating stimuli. A conserved FERM domain basic patch is required for this conformational change and for interaction with a novel ligand for FAK, acidic phospholipids. Binding to phosphatidylinositol 4,5-bisphosphate (PIP2)-containing phospholipid vesicles activated and induced conformational change in FAK in vitro, and alteration of PIP2 levels in vivo changed the level of activation of the conformational biosensor. These findings provide direct evidence of conformational regulation of FAK in living cells and novel insight into the mechanism regulating FAK conformation.

Selected-fit versus induced-fit protein binding: Kinetic differences and mutational analysis

Abstract: The binding of a ligand molecule to a protein is often accompanied by conformational changes of the protein. A central question is whether the ligand induces the conformational change (induced-fit), or rather selects and stabilizes a complementary conformation from a pre-existing equilibrium of ground and excited states of the protein (selected-fit). We consider here the binding kinetics in a simple four-state model of ligand-protein binding. In this model, the protein has two conformations, which can both bind the ligand. The first conformation is the ground state of the protein when the ligand is off, and the second conformation is the ground state when the ligand is bound. The induced-fit mechanism corresponds to ligand binding in the unbound ground state, and the selected-fit mechanism to ligand binding in the excited state. We find a simple, characteristic difference between the on- and off-rates in the two mechanisms if the conformational relaxation into the ground states is fast. In the case of selected-fit binding, the on-rate depends on the conformational equilibrium constant, while the off-rate is independent. In the case of induced-fit binding, in contrast, the off-rate depends on the conformational equilibrium, while the on-rate is independent. Whether a protein binds a ligand via selected-fit or induced-fit thus may be revealed by mutations far from the protein's binding pocket, or other "perturbations" that only affect the conformational equilibrium. In the case of selected-fit, such mutations will only change the on-rate, and in the case of induced-fit, only the off-rate.

Characterization of enzyme motions by solution NMR relaxation dispersion.

Abstract: In many enzymes, conformational changes that occur along the reaction coordinate can pose a bottleneck to the rate of conversion of substrates to products. Characterization of these rate-limiting protein motions is essential for obtaining a full understanding of enzyme-catalyzed reactions. Solution NMR experiments such as the Carr-Purcell-Meiboom-Gill (CPMG) spin-echo or off-resonance R 1rho pulse sequences enable quantitation of protein motions in the time range of microseconds to milliseconds. These experiments allow characterization of the conformational exchange rate constant, k ex, the equilibrium populations of the relevant conformations, and the chemical shift differences (Deltaomega) between the conformations. The CPMG experiments were applied to the backbone N-H positions of ribonuclease A (RNase A). To probe the role of dynamic processes in the catalytic cycle of RNase A, stable mimics of the apo enzyme (E), enzyme-substrate (ES) complex, and enzyme-product (EP) complex were formed. The results indicate that the ligand has relatively little influence on the kinetics of motion, which occurs at 1700 s (-1) and is the same as both k cat, and the product dissociation rate constant. Instead, the effect of ligand is to stabilize one of the pre-existing conformations. Thus, these NMR experiments indicate that the conformational change in RNase A is ligand-stabilized and does not appear to be ligand-induced. Further evidence for the coupling of motion and enzyme function comes from the similar solvent deuterium kinetic isotope effect on k ex derived from the NMR measurements and k cat from enzyme kinetic studies. This isotope effect of approximately 2 depends linearly on solvent deuterium content suggesting the involvement of a single proton in RNase A motion and function. Moreover, mutation of His48 to alanine eliminates motion in RNase A and decreases the catalytic turnover rate indicating the involvement of His48, which is far from the active site, in coupling motion and function. For the enzyme triosephosphate isomerase (TIM), the opening and closing motion of a highly conserved active site loop (loop 6) has been implicated in many studies to play an important role in the catalytic cycle of the enzyme. Off-resonance R 1rho experiments were performed on TIM, and results were obtained for amino acid residues in the N-terminal (Val167), and C-terminal (Lys174, Thr177) portions of loop 6. The results indicate that all three loop residues move between the open and closed conformation at about 10,000 s (-1), which is the same as the catalytic rate constant. The O (eta) atom of Tyr208 provides a hydrogen bond to stabilize the closed form of loop 6 by interacting with the amide nitrogen of Ala176; these atoms are outside of hydrogen bonding distance in the open form of the enzyme. Mutation of Tyr208 to phenylalanine results in significant loss of catalytic activity but does not appear to alter the kex value of the N-terminal part of loop 6. Instead, removal of this hydrogen bond appears to result in an increase in the equilibrium population of the open conformer of loop 6, thereby resulting in a loss of activity through a shift in the conformational equilibrium of loop 6. Solution NMR relaxation dispersion experiments are powerful experimental tools that can elucidate protein motions with atomic resolution and can provide insight into the role of these motions in biological function.

Functional implications of structural differences between variants A and B of bovine beta-lactoglobulin.

Abstract: The structure of the trigonal crystal form of bovine beta-lactoglobulin variant B at pH 7.1 has been determined by X-ray diffraction methods at a resolution of 2.22 A and refined to values for R and Rfree of 0.239 and 0.286, respectively. By comparison with the structure of the trigonal crystal form of bovine beta-lactoglobulin variant A at pH 7.1, which was determined previously [Qin BY et al., 1998, Biochemistry 37:14014-14023], the structural consequences of the sequence differences D64G and V118A of variants A and B, respectively, have been investigated. Only minor differences in the core calyx structure occur. In the vicinity of the mutation site D64G on loop CD (residues 61-67), there are small changes in main-chain conformation, whereas the substitution V118A on beta-strand H is unaccompanied by changes in the surrounding structure, thereby creating a void volume and weakened hydrophobic interactions with a consequent loss of thermal stability relative to variant A. A conformational difference is found for the loop EF, implicated in the pH-dependent conformational change known as the Tanford transition, but it is not clear whether this reflects differences intrinsic to the variants in solution or differences in crystallization.

Conformational flexibility in mammalian 15S‐lipoxygenase: Reinterpretation of the crystallographic data

Abstract: Lipoxygenases (LOXs) are a family of nonheme iron dioxygenases that catalyze the regioselective and stereospecific hydroperoxidation of polyunsaturated fatty acids, and are involved in a variety of inflammatory diseases and cancers. The crystal structure of rabbit 15S-LOX1 that was reported by Gillmor et al. in 1997 has played key roles for understanding the properties of mammalian LOXs. In this structure, three segments, including 12 residues in the superficial α2 helix, are absent and have usually been described as “disordered.” By reinterpreting the original crystallographic data we were able to elucidate two different conformations of the molecule, both having well ordered α2 helices. Surprisingly, one molecule contained an inhibitor and the other did not, thereby adopting a closed and an open form, respectively. They differed in the conformation of the segments that were absent in the original structure, which is highlighted by a 12 A movement of α2. Consequently, they showed a difference in the size and shape of the substrate-binding cavity. The new model should provide new insight into the catalytic mechanism involving induced conformational change of the binding pocket. It may also be helpful for the structure-based design of LOX inhibitors. Proteins 2008. © 2007 Wiley-Liss, Inc.

Irreversible chemical steps control intersubunit dynamics during translation.

Abstract: The ribosome, a two-subunit macromolecular machine, deciphers the genetic code and catalyzes peptide bond formation. Dynamic rotational movement between ribosomal subunits is likely required for efficient and accurate protein synthesis, but direct observation of intersubunit dynamics has been obscured by the repetitive, multistep nature of translation. Here, we report a collection of single-molecule fluorescence resonance energy transfer assays that reveal a ribosomal intersubunit conformational cycle in real time during initiation and the first round of elongation. After subunit joining and delivery of correct aminoacyl-tRNA to the ribosome, peptide bond formation results in a rapid conformational change, consistent with the counterclockwise rotation of the 30S subunit with respect to the 50S subunit implied by prior structural and biochemical studies. Subsequent binding of elongation factor G and GTP hydrolysis results in a clockwise rotation of the 30S subunit relative to the 50S subunit, preparing the ribosome for the next round of tRNA selection and peptide bond formation. The ribosome thus harnesses the free energy of irreversible peptidyl transfer and GTP hydrolysis to surmount activation barriers to large-scale conformational changes during translation. Intersubunit rotation is likely a requirement for the concerted movement of tRNA and mRNA substrates during translocation.

Cleavage and conformational changes of tau protein follow phosphorylation during Alzheimer’s disease

Abstract: Phosphorylation, cleavage and conformational changes in tau protein all play pivotal roles during Alzheimer's disease (AD). In an effort to determine the chronological sequence of these changes, in this study, using confocal microscopy, we compared phosphorylation at several sites (Ser(199/202/396/404/422)-Thr(205) and the second repeat domain), cleavage of tau (D(421)) and the canonical conformational Alz-50 epitope. While all of these posttranslational modifications are found in neurofibrillary tangles (NFTs) at all stages of the disease, we found significantly higher numbers of phospho-tau positive NFTs when compared with cleaved tau (P = 0.006 in Braak III; P = 0.002 in Braak IV; P = 0.012 in Braak V) or compared with the Alz-50 epitope (P < 0.05). Consistent with these findings, in a double transgenic mice model (Tet/GSK-3beta/VLW) overexpressing the enzyme glycogen synthase kinase-3beta (GSK-3beta) and tau with a triple FTDP-17 mutation (VLW) with AD-like neurodegeneration, phosphorylation at sites Ser(199/202)-Thr(205) was greater than truncated tau. Taken together, these data strongly support the notion that the conformational changes and truncation of tau occur after the phosphorylation of tau. We propose two probable pathways for the pathological processing of tau protein during AD, either phosphorylation and cleavage of tau followed by the Alz-50 conformational change or phosphorylation followed by the conformational change and cleavage as the last step.

Design of a Selective Metal Ion Switch for Self-Assembly of Peptide-Based Fibrils

Abstract: The self-assembling peptide TZ1H, a structural variant of the trimeric isoleucine zipper GCN4-pII, contains histidine residues at core d-positions of alternate heptads that define three trigonal coordination sites within the coiled-coil trimer. Circular dichroism spectropolarimetry indicated that peptide TZ1H undergoes a random coil to α-helical conformational change upon binding of 1 equiv of silver(I) ion, but not zinc(II), copper(II), or nickel(II) ions. Isothermal titration calorimetry provided evidence for a single binding-site model in which each peptide contributes one net silver(I) coordination site, in agreement with the proposed structural model. Transmission electron microscopy revealed that TZ1H self-assembles into long aspect ratio helical fibers in the presence of silver(I) ion. These results demonstrate that the rational design of selective metal ion binding sites within de novo designed peptides represents a promising approach to the controlled fabrication of nanoscale, self-assembled mate...

Structure and Function of β-1,4-Galactosyltransferase

Abstract: Beta-1,4-galactosylransferase (beta4Gal-T1) participates in the synthesis of Galbeta1-4-GlcNAc-disaccharide unit of glycoconjugates. It is a trans-Golgi glycosyltransferase (Glyco-T) with a type II membrane protein topology, a short N-terminal cytoplasmic domain, a membrane-spanning region, as well as a stem and a C-terminal catalytic domain facing the trans-Golgi-lumen. Its hydrophobic membrane-spanning region, like that of other Glyco-T, has a shorter length compared to plasma membrane proteins, an important feature for its retention in the trans-Golgi. The catalytic domain has two flexible loops, a long and a small one. The primary metal binding site is located at the N-terminal hinge region of the long flexible loop. Upon binding of metal ion and sugar-nucleotide, the flexible loops undergo a marked conformational change, from an open to a closed conformation. Conformational change simultaneously creates at the C-terminal region of the flexible loop an oligosaccharide acceptor binding site that did not exist before. The loop acts as a lid covering the bound donor substrate. After completion of the transfer of the glycosyl unit to the acceptor, the saccharide product is ejected; the loop reverts to its native conformation to release the remaining nucleotide moiety. The conformational change in beta4Gal-T1 also creates the binding site for a mammary gland-specific protein, alpha-lactalbumin (LA), which changes the acceptor specificity of the enzyme toward glucose to synthesize lactose during lactation. The specificity of the sugar donor is generally determined by a few residues in the sugar-nucleotide binding pocket of Glyco-T, conserved among the family members from different species. Mutation of these residues has allowed us to design new and novel glycosyltransferases, with broader or requisite donor and acceptor specificities, and to synthesize specific complex carbohydrates as well as specific inhibitors for these enzymes.

Src Kinase Conformational Activation: Thermodynamics, Pathways, and Mechanisms

Abstract: Tyrosine kinases of the Src-family are large allosteric enzymes that play a key role in cellular signaling. Conversion of the kinase from an inactive to an active state is accompanied by substantial structural changes. Here, we construct a coarse-grained model of the catalytic domain incorporating experimental structures for the two stable states, and simulate the dynamics of conformational transitions in kinase activation. We explore the transition energy landscapes by constructing a structural network among clusters of conformations from the simulations. From the structural network, two major ensembles of pathways for the activation are identified. In the first transition pathway, we find a coordinated switching mechanism of interactions among the αC helix, the activation-loop, and the β strands in the N-lobe of the catalytic domain. In a second pathway, the conformational change is coupled to a partial unfolding of the N-lobe region of the catalytic domain. We also characterize the switching mechanism for the αC helix and the activation-loop in detail. Finally, we test the performance of a Markov model and its ability to account for the structural kinetics in the context of Src conformational changes. Taken together, these results provide a broad framework for understanding the main features of the conformational transition taking place upon Src activation.

Antigen ligation triggers a conformational change within the constant domain of the alpha/beta T-cell receptor

Abstract: Ligation of the alphabeta T cell receptor (TCR) by a specific peptide-loaded major histocompatibility complex (pMHC) molecule initiates T cell signaling via the CD3 complex. However, the initial events that link antigen recognition to T cell signal transduction remain unclear. Here we show, via fluorescence-based experiments and structural analyses, that MHC-restricted antigen recognition by the alphabeta TCR results in a specific conformational change confined to the A-B loop within the alpha chain of the constant domain (Calpha). The apparent affinity constant of this A-B loop movement mirrored that of alphabeta TCR-pMHC ligation and was observed in two alphabeta TCRs with distinct pMHC specificities. The Ag-induced A-B loop conformational change could be inhibited by fixing the juxtapositioning of the constant domains and was shown to be reversible upon pMHC disassociation. Notably, the loop movement within the Calpha domain, although specific for an agonist pMHC ligand, was not observed with a pMHC antagonist. Moreover, mutagenesis of residues within the A-B loop impaired T cell signaling in an in vitro system of antigen-specific TCR stimulation. Collectively, our findings provide a basis for the earliest molecular events that underlie Ag-induced T cell triggering.

PTEN Phosphatase Selectively Binds Phosphoinositides and Undergoes Structural Changes

Abstract: PTEN (phosphatase and tensin homologue deleted on chromosome 10) is a tumor suppressor that is mutated or deleted in a variety of human tumors, and even loss of only one PTEN gene profoundly affects carcinogenesis. PTEN encodes a phosphatidylinositol phosphate phosphatase specific for the 3-position of the inositol ring. Despite its importance, we are just beginning to understand the regulatory circuits that maintain the correct levels of PTEN phosphatase activity. Several independent studies reported that PI(4,5)P2 enhances PTEN phosphatase activity, but the reasons for this enhancement are currently being debated. In this study, PTEN bound to PI(4,5)P2-bearing vesicles has increased alpha-helicity, providing direct spectroscopic proof of a conformational change. Neither PI(3,5)P2 nor PI(3,4,5)P3 induced this conformational change. On the basis of experiments with two mutant PTEN proteins, it is shown that PI(4,5)P2 induces this conformational change by binding to the PTEN N-terminal domain. Using PTEN protein and a 21-amino acid peptide based on the PTEN N-terminus, we tested all natural phosphatidylinositol phosphates and found preferential binding of PI(4,5)P2. PTEN also binds to phosphatidylserine-bearing vesicles, resulting in a slight increase in beta-sheet content. In addition, PTEN binds synergistically to PI(4,5)P2 and phosphatidylserine, and hence, these anionic lipids do not compete for PTEN binding sites. Collectively, these results demonstrate that PTEN binds to membranes through multiple sites, but only PI(4,5)P2 binding to the N-terminal domain triggers a conformational change with increased alpha-helicity.

Structure of Ca2+-bound S100A4 and its interaction with peptides derived from nonmuscle myosin-IIA.

Abstract: S100A4, also known as mts1, is a member of the S100 family of Ca2+-binding proteins that is directly involved in tumor invasion and metastasis via interactions with specific protein targets, including nonmuscle myosin-IIA (MIIA). Human S100A4 binds two Ca2+ ions with the typical EF-hand exhibiting an affinity that is nearly 1 order of magnitude tighter than that of the pseudo-EF-hand. To examine how Ca2+ modifies the overall organization and structure of the protein, we determined the 1.7 A crystal structure of the human Ca2+-S100A4. Ca2+ binding induces a large reorientation of helix 3 in the typical EF-hand. This reorganization exposes a hydrophobic cleft that is comprised of residues from the hinge region,helix 3, and helix 4, which afford specific target recognition and binding. The Ca2+-dependent conformational change is required for S100A4 to bind peptide sequences derived from the C-terminal portion of the MIIA rod with submicromolar affinity. In addition, the level of binding of Ca2+ to both EF-hands increases by 1 order of magnitude in the presence of MIIA. NMR spectroscopy studies demonstrate that following titration with a MIIA peptide, the largest chemical shift perturbations and exchange broadening effects occur for residues in the hydrophobic pocket of Ca2+-S100A4. Most of these residues are not exposed in apo-S100A4 and explain the Ca2+ dependence of formation of theS100A4-MIIA complex. These studies provide the foundation for understanding S100A4 target recognition and may support the development of reagents that interfere with S100A4 function.

Energetics of solvent and ligand-induced conformational changes in alpha-lactalbumin.

Abstract: The energetics of structural changes in the holo and apo forms of a-lactalbumin and the transition between their native and denatured states induced by binding Ca2+ and Na+ have been studied by differential scanning and isothermal titration microcalorimetry and circular dichroism spectroscopy under various solvent conditions. Removal of Ca2+ from the protein enhances its sensitivity to pH and ionic conditions due to noncompensated negative charge-charge interactions at the cation binding site, which significantly reduces its overall stability. At neutral pH and low ionic strength, the native structure of apo-alpha-lactalbumin is stable below 14 C and undergoes a conformational change to a native-like molten globule intermediate at temperatures above 25 degrees C. The denaturation of either holo- or apo-alpha-lactalbumin is a highly cooperative process that is characterized by an enthalpy of similar magnitude when calculated at the same temperature. Measured by direct calorimetric titration, the enthalpy of Ca2+-binding to apo-LA at pH 7.5 is -7.1 kJ mol(-1) at 5.0 degrees C. which is essentially invariant to protonation effects. This small enthalpy effect infers that stabilization of alpha-lactalbumin by Ca2+ is primarily an entropy driven process, presumably arising from electrostatic interactions and the hydration effect. In contrast to the binding of calcium, the interaction of sodium with apo-LA does not produce a noticeable heat effect and is characterized by its ionic nature rather than specific binding to the metal-binding site. Characterization of the conformational stability and ligand binding energetics of alpha-lactalbumin as a function of solvent conditions furnishes significant insight regarding the molecular flexibility and regulatory mechanism mediated by this protein.

Microcalorimetrics studies of the thermodynamics and binding mechanism between L-tyrosinamide and aptamer.

Abstract: In recent years, several high-resolution structures of aptamer complexes have shed light on the binding mode and recognition principles of aptamer complex interactions. In some cases, however, the aptamer complex binding behavior and mechanism are not clearly understood, especially with the absence of structural information. In this study, it was demonstrated that isothermal titration calorimetry (ITC) and circular dichroism (CD) were useful tools for studying the fundamental binding mechanism between a DNA aptamer and L-tyrosinamide (L-TyrNH2). To gain further insight into this behavior, thermodynamic and conformational measurements under different parameters such as salt concentration, temperature, pH value, analogue of L-TyrNH2, and metal ion were carried out. The thermodynamic signature along with the coupled CD spectral change suggest that this binding behavior is an enthalpy-driven process, and the aptamer has a conformational change from B-form to A-form. The results showed that the interaction is an induced fit binding, and the driving forces in this binding behavior may include electrostatic interactions, hydrophobic effects, hydrogen bonding, and the binding-linked protonation process. The amide group and phenolic hydroxyl group of the L-TyrNH2 play a vital role in this binding mechanism. In addition, it should be noted that Mg(2+) not only improves binding affinity but also helps change the structure of the DNA aptamer.

Energy landscape along an enzymatic reaction trajectory: hinges or cracks?

Abstract: Are the most dynamically flexible regions around the equilibrium structure of an enzyme the same regions involved in the transition state for rate limiting processes involved in the enzymatic reaction? Kern and‐coworkers “Wolf‐Watz et al., 2004; Henzler‐Wildman et al., 2007a, 2007b… have shown that insights about functionally relevant motions that determine the overall enzyme turnover rate can be obtained by investigating conformational dynamics around the equilibrium basin of the enzyme adenylate kinase. An allosteric change in protein structure turns out to be the controlling process. In this commentary we compare results of this study with earlier predictions of the route by which the enzyme undergoes its conformational change. These predictions are based on the idea that the energy surface for the protein is determined by the end structures of the conformational change. A key issue is whether the protein moves by specific hinges or whether it “cracks” and accesses partially unfolded states during its ...