Cooperativity of ligand binding as a function of monomer-dimer equilibrium parameters and acceptor concentration

A general monomer-dimer equilibrium system involving ligand interactions ispresented. Cooperativity features of specific limited models are analyzed by selecting the appropriate family of equilibrium constants from this general scheme. Each system is then characterized in terms of Hill coefficient dependency on alterations in values of equilibrium constants and total acceptor concentration. This method permits comparison of predicted cooperativity trends between systems. Contrasting reports concerning cooperativity dependencies for certain defined equilibrium systems are compared and the discrepancies resolved. Characteristics of cooperativity binding patterns are shown to include symmetry about dimerization association constant values, both positive and negative cooperativity for a single set of parameters, and significant changes in cooperativity features with relatively small changes in equilibrium parameters.     

Structural change in response to ligand binding

The minutiae of subtle changes that occur in response to ligand binding in multiprotein complexes are often difficult to assess without resource to high resolution X-ray analysis. Recent developments in mass spectrometry, however, are providing insight into dynamic changes within components. In this article we review recent applications of MS for selection of ligands and definition of their binding characteristics for individual protein targets through to macromolecular complexes such as ribosomes.     

Microcalorimetric indications for ligand binding as a function of the protein for galactoside-specific plant and avian lectins

The process cascade leading to the final accommodation of the carbohydrate ligand in the lectin's binding site comprises enthalpic and entropic contributions of the binding partners and solvent molecules. With emphasis on lactose, N-acetyllactosamine, and thiodigalactoside as potent inhibitors of binding of galactoside-specific lectins, the question was addressed to what extent these parameters are affected as a function of the protein. The microcalorimetric study of carbohydrate association to the galectin from chicken liver (CG-16) and the agglutinin from Viscum album (VAA) revealed enthalpy-entropy compensation with evident protein type-dependent changes for N-acetyllactosamine. Reduction of the entropic penalty by differential flexibility of loops or side chains and/or solvation properties of the protein will have to be reckoned with to assign a molecular cause to protein type-dependent changes in thermodynamic parameters for lectins sharing the same monosaccharide specificity.     

The biotin-thyroxin conjugate as a bifunctional ligand of binding proteins

The conjugate of the residue of vitamin H (biotin, Bt) with the hormone of thyroid gland thyroxin (T₄) was prepared by N-acylation of N-(3-aminopropyl)biotin amide with N-hydroxysuccinimide ester of N-acetyl thyroxin. The interactions of the Bt-T₄ conjugate with one or simultaneously with two binding proteins with affinity to Bt or T₄ in solution and on a solid phase were studied by electron spectroscopy, enzyme immunoassay, and computer modeling. Bt-T₄ was specifically fixed in the Bt-binding site of the streptavidin molecule via a large number of hydrogen bonds and hydrophobic interactions. The maximum of the streptavidin fluorescence shifted to a long-wave area and its intensity decreased as a result of complex formation. The degree of quenching of the protein emission was significantly higher than that of the streptavidin-Bt complex. Additional fluorescence quenching resulted from interactions which were sensitive to pH, ionic strength, and detergents and stabilized the position of the thyroxin part of the conjugate near Trp120 of streptavidin in its complex with Bt-T₄. The Bt-T₄ conjugate also formed a specific equimolar complex with T₄-binding human globulin (TBG) by the same mechanism as that for T₄. The Bt residue did not participate in the interactions which changed characteristics of the TBG fluorophores. The Bt-T₄ conjugate was bound to avidin on a solid phase in the solid phase enzyme immunoassay owing to its biotin function, whereas its thyroxin part was exposed to a solution and interacted with polyclonal antibodies to T₄. The intact T₄ competitively inhibited this interaction after its addition to the system. Bt-T₄ also exhibited its bifunctional activity in other immune analytic system. The conjugate bound streptavidin was labeled with Eu³⁺-chelate and subsequently formed a three component complex with participation of a monoclonal antibody to T₄ immobilized on a solid phase. Free T₄ inhibited the thyroxin function of the conjugate bound to the labeled streptavidin proportionally to its concentration in a sample of human blood serum. Parameters of the immunofluorescent analysis demonstrated that the streptavidin-Bt-T₄ complex was actively bound to the T₄-antibody, but had practically no interaction with serum T₄-binding proteins, including TBG. Probably, nonspecific interactions of the T₄ residue with streptavidin in its complex with Bt-T₄, along with steric factors, complicated penetration of thyroxin in this complex into active sites of TBG and other T₄-binding proteins of blood serum. The Bt-T₄ stable conjugate was synthesized according to a plain scheme and could be used as a bifunctional ligand of binding proteins in biochemical studies and immune analytical systems for medicinal diagnostics.     

Volume of Hsp90 ligand binding and the unfolding phase diagram as a function of pressure and temperature

Volume changes that accompany protein unfolding and ligand binding are important but largely neglected thermodynamic parameters that may facilitate rational drug design. Here, we determined the volume of lead compound ICPD47 binding to an anticancer target, heat shock protein 90 N-terminal domain, using a pressure shift assay (PressureFluor). The ligand exhibited a stabilizing effect on the protein by increasing its melting pressure and temperature. The Gibbs free energy of unfolding depends on the absence or presence of ligand and has an elliptical shape. Ellipse size increases upon addition of the strongly binding ligand, which stabilizes the protein. The three-dimensional (3D) ellipsoidal surface of the Gibbs free energy of unfolding was calculated with increasing ligand concentrations. The negative volume of ligand binding was relatively large and significantly exceeded the volume of protein unfolding. The pressure shift assay technique could be used to determine the volume changes associated with both protein unfolding as well as ligand binding to protein.     

Correlation between protein function and ligand binding profiles

We report that proteins with the same function bind the same set of small molecules from a standardized chemical library. This observation led to a quantifiable and rapidly adaptable method for protein functional analysis using experimentally derived ligand binding profiles. Ligand binding is measured using a high-throughput NMR ligand affinity screen with a structurally diverse chemical library. The method was demonstrated using a set of 19 proteins with a range of functions. A statistically significant similarity in ligand binding profiles was only observed between the two functionally identical albumins and between the five functionally similar amylases. This new approach is independent of sequence, structure, or evolutionary information and, therefore, extends our ability to analyze and functionally annotate novel genes.     

Cyclic ferrocenylnaphthalene diimide derivative as a new class of G-quadruplex DNA binding ligand

To identify an effective ligand that binds to a G-quadruplex structure but not a double-stranded DNA (dsDNA), a set of biophysical and biochemical experiments were carried out using newly synthesized cyclic ferrocenylnaphthalene diimide (cFNDI, 1) or the non-cyclic derivative (2) with various structures of G-quadruplex DNAs and dsDNA. Compound 1 bound strongly to G-quadruplexes DNAs (10⁶ M^?1 order) with diminished binding to dsDNA (10⁴ M^?1 order) in 100 mM AcOH-AcOK buffer (pH 5.5) containing 100 mM KCl. Interestingly, 1 showed an approximately 50-fold higher selectivity to mixed hybrid-type telomeric G-quadruplex DNA (K = 3.4 × 10⁶ M^?1 and a 2:1 stoichiometry) than dsDNA (K = 7.5 × 10⁴ M^?1) did. Furthermore, 1 showed higher thermal stability to G-quadruplex DNAs than it did to dsDNA with a preference for c-kit and c-myc G-quadruplex DNAs over telomeric and thrombin binding aptamers. Additionally, 1 exhibited telomerase inhibitory activity with a half-maximal inhibitory concentration (IC₅₀) of 0.4 μM. Compound 2 showed a preference for G-quadruplex; however, the binding affinity magnitude and preference were improved in 1 because the former had a cyclic structure.     

Relative ligand binding to small or large aggregates measured by scanning correlation spectroscopy.

Cell surface receptors transduce signals, required to produce cellular activity, that may be mediated by ligand-induced receptor aggregation. Several receptor systems exhibit both low and high ligand affinities and some models of receptor activation associate receptor clusters with high or low ligand binding affinity. In the present work succinyl concanavalin A, which binds with both high and low affinity to receptors, was studied on 3T3 Swiss mouse fibroblasts, where preaggregation of receptors has been postulated. Scanning fluorescence correlation spectroscopy measurements were used to determine the relationship between the degree of ligand binding and the state of receptor aggregation. Correlation analysis of fluorescence fluctuations across the cell surface reveal that the variance of the fluctuations (quantitated by g[0]) increased when the ligand concentration was varied from 0.33 to 67 mg/L. The g(0) values reached a plateau at concentrations greater than approximately 10 mg/L. These data are incompatible with homogeneous receptor distributions or equal affinity receptor binding but are compatible with a partly aggregated receptor system with high affinity binding to small aggregates, and low affinity binding to large aggregates. Computer simulated scanning fluorescence correlation spectroscopy experiments confirm that background fluorescence from the cell does not account for the experimentally observed effects.     

The dynamical response of hen egg white lysozyme to the binding of a carbohydrate ligand

It has become clear that the binding of small and large ligands to proteins can invoke significant changes in side chain and main chain motion in the fast picosecond to nanosecond timescale. Recently, the use of a "dynamical proxy" has indicated that changes in these motions often reflect significant changes in conformational entropy. These entropic contributions are sometimes of the same order as the total entropy of binding. Thus, it is important to understand the connections amongst motion between the manifold of states accessible to the native state of proteins, the corresponding entropy, and how this impacts the overall energetics of protein function. The interaction of proteins with carbohydrate ligands is central to a range of biological functions. Here, we examine a classic carbohydrate interaction with an enzyme: the binding of wild-type hen egg white lysozyme (HEWL) to the natural, competitive inhibitor chitotriose. Using NMR relaxation experiments, backbone amide and side chain methyl axial order parameters were obtained across apo and chitotriose-bound HEWL. Upon binding, changes in the apparent amplitude of picosecond to nanosecond main chain and side chain motions are seen across the protein. Indeed, binding of chitotriose renders a large contiguous fraction of HEWL effectively completely rigid. Changes in methyl flexibility are most pronounced closest to the binding site, but average to only a small overall change in the dynamics across the protein. The corresponding change in conformational entropy is unfavorable and estimated to be a significant fraction of the total binding entropy.     

A spectral correlation function for efficient sequential NMR assignments of uniformly 15N-labeled proteins

Summary A new computer-based approach is described for efficient sequence-specific assignment of uniformly ¹⁵N-labeled proteins. For this purpose three-dimensional ¹⁵N-correlated [¹H, ¹H]-NOESY spectra are divided up into two-dimensional ¹H-¹H strips which extend over the entire spectral width along one dimension and have a width of ca. 100 Hz, centered about the amide proton chemical shifts along the other dimension. A spectral correlation function enables sorting of these strips according to proximity of the corresponding residues in the amino acid sequence. Thereby, starting from a given strip in the spectrum, the probability of its corresponding to the C-terminal neighboring residue is calculated for all other strips from the similarity of their peak patterns with a pattern predicted for the sequentially adjoining residue, as manifested in the scalar product of the vectors representing the predicted and measured peak patterns. Tests with five different proteins containing both -helices and -sheets, and ranging in size from 58 to 165 amino acid residues show that the discrimination achieved between the sequentially neighboring residue and all other residues compares well with that obtained with an unguided interactive search of pairs of sequentially neighboring strips, with important savings in the time needed for complete analysis of 3D ¹⁵N-correlated [¹H, ¹H]-NOESY spectra. The integration of this routine into the program package XEASY ensures that remaining ambiguities can be resolved by visual inspection of the strips, combined with reference to the amino acid sequence and information on spin-system types obtained from additional NMR spectra.Abbreviations 1D, 2D, 3D, 4D one-, two-, three-, four-dimensional - NOE nuclear Overhauser enhancement - NOESY nuclear Overhauser enhancement spectroscopy - COSY correlation spectroscopy - TOCSY total correlation spectroscopy     

Co-operative response of oligomeric protein receptors coupled to non-co-operative ligand binding.

The biogenesis of 30 S and 50 S ribosomal subunits in exponentially growing Escherichia coli has been studied by following the rate of appearance of pulse-labelled ribosomal proteins on mature subunits. Cells were pulse-labelled for two minutes and for three and a half minutes with radioactive leucine. Ribosomal proteins were extracted and purified by chromatography on carboxymethyl cellulose and analysed by bidimensional gel electrophoresis. All 30 S proteins and most of the 50 S proteins were thus prepared and their radioactivity counted: unequal labelling was obtained. 30 S and 50 S proteins were ordered according to increasing specific radioactivity at both time pulses. The incorporation was greater at three and a half minutes than at two minutes. No major difference in the order at the two labelling times was observed.Only two classes of proteins can be defined in the 30 S and the 50 S subunits, namely early and late proteins. In each class a gradual increase in the radioactivity is apparent from the poorly labelled to the highly labelled proteins. This suggests a definite order of addition.Early 30 S proteins: S17, S16, S15, S19, S18, S8, S4, S20, S10, S6, S9, S12, S7.Late 30 S proteins: S5, S3, S2, S14, S11, S13, S1, S21.Early 50 S proteins: L22, L20, L21, L4, L13, L16, L3, L23, L18, L24, L28, L17, L19, L29, L32, L5, L15, L2, L30, L27.Late 50 S proteins: L25, L11, L7, L12, L1, L9, L8, L10, L33, L14, L6.This order is discussed taking into account the pool size of the proteins measured in the same conditions of cell culture.     

Studies of lysozyme binding to histamine as a ligand for hydrophobic charge induction chromatography

Histamine was immobilized on Sepharose CL‐6B (Sepharose) for use as a ligand of hydrophobic charge induction chromatography (HCIC) of proteins. Lysozyme adsorption onto Histamine‐Sepharose (HA‐S) was studied by adsorption equilibrium and calorimetry to uncover the thermodynamic mechanism of the protein binding. In both the experiments, the influence of salt (ammonium sulfate and sodium sulfate) was examined. Adsorption isotherms showed that HA‐S exhibited a high salt tolerance in lysozyme adsorption. This property was well explained by the combined contributions of hydrophobic interaction and aromatic stacking. The isotherms were well fitted to the Langmuir equation, and the equilibrium parameters for lysozyme adsorption were obtained. In addition, thermodynamic parameters (ΔH_ads, ΔS_ads, and ΔG_ads) for the adsorption were obtained by isothermal titration calorimetry by titrating lysozyme solutions into the adsorbent suspension. Furthermore, free histamine was titrated into lysozyme solution in the same salt‐buffers. Compared with the binding of lysozyme to free histamine, lysozyme adsorption onto HA‐S was characterized by a less favorable ΔG_ads and an unfavorable ΔS_ads because histamine was covalently attached to Sepharose via a three‐carbon‐chain spacer. Consequently, the immobilized histamine could only associate with the residues on the protein surface rather than those in the hydrophobic pocket, causing a less favorable orientation between histamine and lysozyme. Further comparison of thermodynamic parameters indicated that the unfavorable ΔS_ads was offset by a favorable ΔH_ads, thus exhibiting typical enthalpy‐entropy compensation. Moreover, thermodynamic analyses indicated the importance of the dehydration of lysozyme molecule and HA‐S during the adsorption and a substantial conformational change of the protein during adsorption. The results have provided clear insights into the adsorption mechanisms of lysozyme onto the new HCIC material. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Thyroid hormone receptor dimerization function maps to a conserved subregion of the ligand binding domain.

Thyroid hormone receptors (TRs) bind as dimers to specific DNA response elements. We have used a genetic approach to identify amino acid sequences required for dimerization of the TR beta isoform. Bacteria expressing a chimeric repressor composed of the DNA binding domain of the bacteriophage lambda cl repressor fused to the TR beta ligand binding domain are immune to lambda infection as a consequence of homodimerization activity provided by the receptor sequences. The phenotypes of deletions and point mutations of the TR beta sequences map dimerization activity to a subregion of the ligand binding domain that is highly conserved among all members of the nuclear hormone receptor superfamily. These results confirm and extend previous findings indicating that this subregion plays an important role in the dimerization of TR beta and other superfamily members.