Evidence for a common high affinity binding site on glutathione S-transferase B for lithocholic acid and bilirubin

Binding of lithocholic acid, bilirubin, and gossypol to glutathione S-transferase B (ligandin or transferase YaYc) was compared using four methods. Tryptophan quenching revealed a single high affinity site for bilirubin and gossypol but could not be used for lithocholic acid. Both displacement of the fluorescent probe, 1-anilino-8-naphthalenesulfonate, and spectral changes induced by bilirubin binding demonstrated a common high affinity site for which all three ligands compete. Similar results were obtained by equilibrium dialysis. The dissociation constants for the binding of both bilirubin and lithocholic acid were comparable with the various methods (range 0.2-0.7 microM). Thus, lithocholic acid and bilirubin share a high affinity binding site on gluthathione S-transferase B that appears to be separate from the binding site for substrates.     

Fluorescence study of the ligand stereospecificity for binding to lumazine protein.

6,7-Dimethyllumazine derivatives, substituted at the 8-position with aldityls or monohydroxyalkyl groups, have been examined for their binding ability to lumazine apo-protein from two strains of Photobacterium phosphoreum using fluorescence dynamics techniques. On the protein the lumazine has a nearly monoexponential decay of fluorescence with lifetime 13.8 ns (20 degrees C). In free solution the lifetime is 9.6 ns. The concentration of free and bound lumazine in an equilibrium mixture can be recovered readily by analysis of the fluorescence decay. Only the aldityl derivatives D-xylityl and 3'-deoxy-D-ribityl, having stereoconfigurations at the 2' and 4' positions identical to the natural ligand, 8-(1'-D-ribityl), show comparable dissociation constants (0.3 microM, 20 degrees C, pH 7.0). D-Erythrityl and L-arabityl have dissociation constants of 1-2 microM. All other ligands show no interaction at all or have dissociation constants in the range 6-80 microM, which can still be determined semi-quantitatively using the fluorescence decay technique. In the case of these very weakly bound ligands, unambiguous detection of bound ligand can be shown by a long correlation time (23 ns, 2 degrees C) for the fluorescence anisotropy decay. Examination of the bound D-xylityl compound's fluorescence anisotropy decay at high time resolution (< 100 ps) shows rigid association, i.e. no mobility independent of the macromolecule. All bound ligands appear to be similarly positioned in the binding site. The influence of the stereoconfiguration at the 8-position found for lumazine protein parallels that previously observed for the enzyme riboflavin synthase, where the lumazines are substrates or inhibitors. This is consistent with the finding of significant sequence similarity between these proteins. The binding rigidity may have implications for the mechanism of the enzyme.     

Covalent labeling of the nonsubstrate ligand-binding site of glutathione S-transferases with bilirubin-Woodward's reagent K

The dimeric enzyme glutathione S-transferase B is composed of two dissimilar subunits, referred to as Ya and Yc. Transferase YaYc and the YaYa homodimer were purified from rat liver cytosol. An enol ester derivative of bilirubin (bilirubin-Woodward's reagent K) was prepared and used to label covalently the nonsubstrate ligand-binding site on these two proteins. There was a linear relationship between the amount of bilirubin-Woodward's reagent K added to the reaction mixture and the amount of labeling achieved up to a ratio of 2:1 (bilirubin-Woodward's reagent K: protein-YaYc). A maximum of 0.87 mol of label bound per mol of transferase YaYc. At higher molar ratios, the label appeared to also be binding at a second site on the enzyme. The label blocked the nonsubstrate ligand-binding site of the two transferases but not the catalytic site. The divalent reagent was shown to label equally the Ya and Yc subunits of transferase YaYc, suggesting that the single high affinity bilirubin-binding site present on this protein is formed by an interaction between the subunits rather than residing on a specific subunit. At low ratios of label to protein, bilirubin-Woodward's reagent K appears to label specifically the nonsubstrate ligand-binding site of two forms of glutathione S-transferase, and use of this label should allow for the localization of the nonsubstrate ligand-binding site in the primary amino acid sequence of the Ya and Yc subunits.     

The effect of C-terminal helix stabilization on specific DNA binding by monomeric GCN4 peptides.

DNA binding by a 29-residue, monomeric, GCN4 basic region peptide, GCN4br, as well as by peptide br-C, a monomeric basic-region analogue that is helix stabilized at its C-terminal end by a Lys25. Asp29 side-chain lactam-bridged alanine-rich sequence, was studied at 25 C in an aqueous buffer containing 100 mm NaCl. Mixing of both peptides with duplex DNA containing the cAMP-responsive element (CRE) was accompanied by significant helix stabilization in the peptides, whereas mixing of the peptides with duplex DNA containing a scrambled CRE site was not. Peptide NBD-br-C was synthesized as a fluorescent probe to evaluate these peptide-DNA interactions further. Quantitative analysis of the fluorescence quenching of peptide NBD-br-C by CRE half-site DNA indicated the formation of a 1:1 complex with a dissociation constant of 1.41 +/- 0.22 microm. Competitive displacement fluorescence assays of CRE half-site binding gave dissociation constants of 0.65 +/- 0.09 microm for peptide br-C and 3.9 +/- 0.5 microM for GCN4br, which corresponds to a free energy difference of 1.1 kcal/mol that is attributed to the helix stabilization achieved in peptide br-C. This result indicates that helix initiation by the alpha-helical leucine zipper dimerization motif in native bzip proteins, such as GCN4, contributes significantly to the affinity of basic region peptides for their recognition sites on DNA. Our fluorescence assay should also prove useful for determining dissociation constants for CRE binding by other GCN4 basic region analogues under equilibrium conditions and physiological salt concentrations.     

Real-time monitoring of hairpin ribozyme kinetics through base-specific quenching of fluorescein-labeled substrates.

Current methods for evaluating the kinetics of ribozyme-catalyzed reactions rely primarily on the use of radiolabeled RNA substrates, and so require tedious electrophoretic separation and quantitation of reaction products for each data point in any experiment. Here, we report the use of fluorescent substrates for real-time analysis of the time course of reactions of the hairpin ribozyme. Fluorescence of 3' fluorescein-labeled substrates was quenched upon binding to the hairpin ribozyme or its isolated substrate-binding strand (SBS), under conditions of ribozyme or SBS excess. This decrease was accompanied by an increase in anisotropy, and resulted from a base-specific quenching by a guanosine residue added to the 5' end of the SBS, close to fluorescein in the complex. Fluorescence quenching was used to determine rate constants for substrate binding (1.4 x 10(8) M(-1) min(-1)), cleavage (0.15 min(-1)), and substrate dissociation (0.010 min(-1)) by a structurally well-defined ribozyme at 25 degrees C in 50 mM Tris-HCI, pH 7.5, 12 mM MgCl2. These rates are in excellent agreement with those obtained using traditional radioisotopic methods. Measurements of dissociation rates provided physical support for interdomain interactions within the substrate-ribozyme complex. We estimate that 2.1 kcal/mol of additional substrate binding energy is provided by the B domain of the ribozyme. Part of this free energy apparently stems from coaxial stacking of helices in the hinge region between domains, and it is plausible that the remainder might be contributed by direct interactions with loop B. The fluorescence quenching and dequenching methods described here should be readily adaptable to studying a wide variety of RNA interactions and reactions using ribozymes and other model systems.     

Binding of biliverdin, bilirubin, and thyroid hormones to lipocalin-type prostaglandin D synthase.

Lipocalin-type prostaglandin D synthase is a major protein of the cerebrospinal fluid and was originally known as beta-trace. We investigated the binding ability of prostaglandin D synthase toward bile pigments, thyroid hormones, steroid hormones, and fatty acids in this present study. We found that the recombinant enzyme binds bile pigments and thyroid hormones, resulting in quenching of the intrinsic tryptophan fluorescence, the appearance of induced circular dichroism of the lipophilic ligands, and a red shift of the absorption spectra of bilirubin and biliverdin. The binding of prostaglandin D synthase to lipophilic ligands was also demonstrated by the resonant mirror technique and surface plasmon resonance detection. The dissociation constants were calculated to be 33 nM, 37 nM, 660 nM, 820 nM, and 2.08 microM for biliverdin, bilirubin, L-thyroxine, 3,3',5'-triiodo-L-thyronine, and 3,3', 5-triiodo-L-thyronine, respectively. Biliverdin and bilirubin underwent a shift in their absorption peaks from 375 to 380 nm and from 439 to 446 nm, respectively, after binding to prostaglandin D synthase. Bilirubin bound to the enzyme showed a bisignate CD spectrum with a (-) Cotton effect at 422 nm and a (+) Cotton effect at 472 nm, indicating a right-handed chirality. The ligands also inhibited prostaglandin D synthase activity noncompetitively in a concentration-dependent manner, with IC50 values between 3.9 and 10. 9 microM. Epididymal retinoic acid-binding protein and beta-lactoglobulin, two other lipocalin proteins that bind retinoids such as prostaglandin D synthase, did not show any significant interaction with bile pigments or thyroid hormones. These results show that prostaglandin D synthase binds small lipophilic ligands with a specificity distinct from that of other lipocalins.     

Hepatic microsomal bilirubin UDP-glucuronosyltransferase. The kinetics of bilirubin mono- and diglucuronide synthesis.

Hepatic biotransformation of bilirubin to the hydrophilic species bilirubin mono- (BMG) and diglucuronide (BDG) by microsomal bilirubin UDP-glucuronosyl-transferase (GT) is a prerequisite for its physiologic excretion into bile. The reaction mechanism of bilirubin-GT and the access of bilirubin and BMG (the intermediate substrate) to the active site of bilirubin-GT are undefined. Highly purified [14C]bilirubin and [3H] BMG were coincubated with rat liver microsomes, and the initial rates of radiolabeled bilirubin glucuronide synthesis were measured. Although these substrates differ markedly in their hydrophilicity, no significant differences were observed in [14C]- and [3H]BDG rates of formation from equimolar [14C]bilirubin and [3H] BMG, in the absence or presence of soluble binding proteins (albumin and hepatic cytosol). In further kinetic studies, [14C]bilirubin and [3H]BMG exhibited mutually competitive inhibition of [3H]- and [14C]BDG synthesis, respectively, and [3H]BMG also inhibited [14C]BMG formation. Finally, unlabeled BMG and BDG inhibited the glucuronidation of [14C]bilirubin, with all three pigments yielding virtual Michaelis-Menten dissociation constants in the 10-20 microM range. These findings indicate that: 1) bilirubin-GT follows Michaelis-Menten kinetics for both bilirubin and BMG glucuronidation over the range of substrate concentrations employed; 2) the findings are consistent with a single active site for the enzymatic synthesis of both BMG and BDG; 3) bilirubin, BMG, and BDG bind competitively to this active site with comparable affinities; and 4) access of both bilirubin and BMG substrates to the enzymatic active site is reduced by soluble binding proteins.     

2'Halo-ATP and -GTP analogues: rational phasing tools for protein crystallography

The solution of the crystallographic macromolecular phase problem requires incorporation of heavy atoms into protein crystals. Several 2'-halogenated nucleotides have been reported as potential universal phasing tools for nucleotide binding proteins. However, only limited data are available dealing with the effect of 2'-substitution on recognition by the protein. We have determined equilibrium dissociation constants of 2'-halogenated ATP analogues for the ATP binding proteins UMP/CMP kinase and the molecular chaperone DnaK. Whereas the affinities to UMP/CMP kinase are of the same order of magnitude as for unsubstituted ATP, the affinities to DnaK are drastically decreased to undetectable levels. For 2'-halogenated GTP analogues, the kinetics of interaction were determined for the small GTPases p21ras(Y32W) (fluorescent mutant) and RabS. The rates of association were found to be within about one order of magnitude of those for the nonsubstituted nucleotides, whereas the rates of dissociation were accelerated by factors of approximately 100 (p21ras) or approximately 10(5) (Rab5), and the resulting equilibrium dissociation constants are in the nm or microM range, respectively. The data demonstrate that 2'halo-ATP and -GTP are substrates or ligands for all proteins tested except the chaperone DnaK. Due to the very high affinities of a large number of GTP binding proteins to guanine nucleotides, even a 10(5)-fold decrease in affinity as observed for Rab5 places the equilibrium dissociation constant in the microM range, so that they are still well suited for crystallization of the G-protein:nucleotide complex.     

Influence of various fluorescent and non-fluorescent labels on the kinetics of the complex formation of alpha-chymotrypsin with basic pancreatic trypsin inhibitor (Kunitz).

The association of alpha-chymotrypsin with basic pancreatic trypsin inhibitor was studied using extrinsic signals produced by fluorescent and nonfluorescent labels. The reactive dyes were covalently bound to the proteins in the complexed state, in which the binding region was protected. The signals were sufficiently large to measure the complex formation at protein concentrations of 10(-9)M by fluorescence and down to 10(-6)M by absorption. Therefore, the association and dissociation could be followed over a broad range of concentration. Good correspondence was observed between data which were obtained with different labels and with published values for the unlabeled proteins. Existing differences could be explained by different buffer conditions used by the different authors. Also the pH dependence of the dissociation rate constants was essentially unaltered by the introduction of the labels. The large signals allowed a direct measurement of the equilibrium constants of dissociation, even at high pH, at which they are in the range of 10(-8)M. The experimentally determined binding constants were in agreement with those calculated from the rate constants. The temperature dependence of the binding constants revealed a small positive and pH-dependent enthalpy change [deltaHo = 4.0 kcal/mol (16.7 kJ) at H 7.0[. The results prove that the labeling can be performed in such a way that the equilibrium and kinetic parameters of the system studied are not significantly influenced.     

Macromolecular binding equilibria in the lac repressor system: studies using high-pressure fluorescence spectroscopy

High hydrostatic pressure coupled with fluorescence polarization has been used to investigate protein subunit interactions and protein-operator association in lac repressor labeled with a long-lived fluorescent probe. On the basis of observation of a concentration-dependent sigmoidal decrease in the dansyl fluorescence polarization, we conclude that application of high hydrostatic pressure results in dissociation of the lac repressor tetramer. The 2-fold decrease in the rotational relaxation time and the high-pressure plateau are consistent with a tetramer to dimer transition. The volume change for tetramer dissociation to dimer is -82 +/- 5 mL/mol. The dissociation constant calculated from the data taken at 4.5 degrees C is 4.3 +/- 1.3 nM. The tetramer dissociation constant increases by a factor of 3 when the temperature is raised from 4.5 to 21 degrees C. A very small effect of inducer binding on the subunit dissociation is observed at 4.5 degrees C; the Kd increases from 4.5 to 7.1 nM. At 21 degrees C, however, inducer binding stabilizes the tetramer by approximately 0.8 kcal/mol. Pressure-induced monomer formation is indicated by the curves obtained upon raising the pH to 9.2. The addition of IPTG shifts the pressure transition to only slightly higher pressures at this pH, indicating that the stabilization of the tetramer by inducer is not as marked as that observed at pH 7.1. From the decrease in the polarization of the dansyl repressor-operator complexes, we also conclude that the application of pressure results their dissociation and that the volume change is large in absolute value (approximately 200 mL/mol). The lac repressor-operator complex is more readily dissociated upon the application of pressure than the tetramer alone, indicating that operator binding destabilizes the lac repressor tetramer.     

Interactions of bilirubin and other ligands with ligandin.

Circular dichroism methods were used to study the structure of rat ligandin and the binding of organic anions to the protein. Ligandin has a highly ordered secondary structure with about 40%alpha helix, 15% beta structure, and 45% random coil. Bilirubin binding occurred primarily at a single high affinity site on the protein. The binding constant for bilirubin (5 X 10-7 Mminus 1) was the highest among the ligands studied. The bilirubin-ligandin complex exhibited a well-defined circular dichroic spectrum with two major overlapping ellipticity bands of opposite sign in the bilirubin absorption region. This spectrum was virtually a mirror image of that of human or rat serum albumin-bilirubin complexes. Studies on the direct transfer of bilirubin from ligandin to rat serum albumin showed that sasociation constants of bilirubin-ligandin complexes were approximately tenfold less than those of the bilirubin-albumin system. Ligandin exhibited a broad specificity with respect to the typeof ligand bond. A series of organic anions inclucing dyes used clinically for liver function tests, fatty acids, hormones, heme derivatives, bile acids, and other ligands that were considered likely to interact with ligandin, were examined. Most induced ellipticity changes consistent with competitive displacement of bilirubin from ligandin and relative affinities of these compounds for ligandin were determined based on their effectiveness in desplacing the bilirubin. Some substances such as glutathione, conjugated sulfobromophthaleins and lithocholic acid bound to ligandin but induced anomalous spectral shifts, when added to ligandin-bilirubin complexes. Other compounds, including some that act as substrates for the glutathione transferase activity exhibited by ligandin, revealed no apparent competitive effects with respect to the bilitubin binding site.     

Protein-ligand binding detected using ultrafiltration Raman difference spectroscopy

A new ultra-filtration-Raman-difference (UFRD) method facilitates the tag-free screening and quantitation of protein-ligand binding constants. The method relies on drop-coating-deposition-Raman (DCDR) combined with ultrafiltration and difference spectroscopy. Ultrafiltration is used to remove free (unbound) ligands from pre-equilibrated protein/ligand solutions. Difference DCDR spectroscopy is used to detect binding-induced vibrational spectral changes obtained from proteins with and without a bound ligand. The capabilities of the UFRD method are demonstrated using the binding of 2,4-dinitrophenol (DNP) to transthyretin (TTR), as well as preliminary measurements in several other systems. The UFRD results clearly reveal DNP spectral features induced by binding to TTR and confirm that only a 1:1 complex is formed even under 10-fold excess DNP conditions. The UFRD method is shown to be most useful when applied to strongly Raman active ligands (such as aromatic compounds). Weakly Raman-active ligands (such as sugars) are typically not compatible with UFRD detection (unless they produce a sufficiently large binding-induced change in protein secondary structure). Theoretical predictions suggest that UFRD may be used to screen binding events with a dissociation constant cut-off of the order of 10 microM, and perhaps also to quantify dissociation constants in the 100 nM to 100 microM range.     

The binding of substrates and a product of the enzymatic reaction to glutathione S-transferase A.

The binding of substrates and a product to glutathione S-transferase A from rat liver was studied by use of equilibrium dialysis and equilibrium partition in a two-phase system. The radioactive substrates glutathione and bromosulfophthalein as well as a product of glutathione and 3,4-dichloro-1-nitrobenzene, S-(2-chloro-4-nitrophenyl)glutathione, gave hyperbolic binding isotherms with a stoichiometry of 2 mol per mol of enzyme (i.e. 1 molecule per subunit). Glutathione (and glutathione disulfide) had an equilibrium (dissociation) constant for the binding of about 10 microM, whereas bromosulfophthalein and the product had equilibrium constants of about 0.5 microM. All ligands showed the same binding stoichiometry, and competition experiments involving unlabeled ligands indicated that glutathione and the glutathione derivatives were binding to the same site. Low affinity sites appeared to exist in addition to the specific high affinity sites (one per subunit) for all ligands tested. The binding studies are fully consistent with a steady state random kinetic mechanism for the enzyme.     

The effect of ligand presaturation on the interaction of serum albumins with an immobilized Cibacron Blue 3G-A studied by affinity gel electrophoresis.

The interaction of the immobilized triazine dye Cibacron Blue 3G-A with rat, rabbit, sheep, goat, bovine and human serum albumins was studied by affinity gel electrophoresis. Dissociation constants were estimated in each instance and showed human serum albumin to have a significantly higher affinity for the dye than did albumin from any other species. Pretreatment of the defatted proteins with bilirubin (3 mol of bilirubin/mol of protein) did not increase the dissociation constants of the serum albumins, whereas pretreatment with palmitate (7 mol of palmitate/mol of protein) increased the dissociation constant in all cases: 3-fold for human serum albumin, 15-fold for other serum albumins. Increasing the bilirubin/albumin ratio (to 7:1) did not affect the dissociation constant of the albumins studied. Decreasing the palmitate/albumin ratio decreased the dissociation constant for human serum albumin, but did not affect those of bovine and rat albumins. Altering the chain length of the presaturating fatty acid dramatically changed the dissociation constant of both human and bovine serum albumins. Butyrate, hexanoate, octanoate and decanoate did not significantly influence the dissociation constants of bovine and human serum albumins for Cibacron Blue, whereas laurate, myristate and palmitate greatly increased the dissociation constant. These data are discussed in relationship to the behaviour of albumins during dye--agarose column chromatography. In Addendum the effect of nucleotide presaturation on the interaction between Bacillus stearothermophilus 6-phosphogluconate dehydrogenase and the immobilized triazine dyes Cibacron Blue 3G-A and Procion Red HE-3B was examined, and the implications for dye--ligand chromatography are discussed.     

Ribonucleotide reductase from Escherichia coli. Identification of allosteric effector sites by chromatography on immobilized effectors.

Ribonucleotide reductase is responsible for the production of deoxyribonucleotides by catalyzing the reduction of ribonucleoside diphosphates. The enzyme is allosterically regulated in a complex way by the nucleoside triphosphates, ATP, dTTP, dGTP, dCTP, and dATP. Ribonucleotide reductase consists of two nonidentical subunits, proteins B1 and B2. Both substrates and allosteric effectors bind exclusively to B1. Binding of protein B1 to dTTP or dATP covalently coupled to Sepharose and elution with concentration gradients of the different nucleoside triphosphate effectors gave information about (1) the arrangement of the effector binding sites on protein B1 and (2) the affinity of the effectors for these sites. Protein B1 thus has two classes of effector binding sites. One class binds all effectors, as demonstrated by elution of the protein from dTTP-Sepharose with dATP, dGTP, ATP, or dCTP. The second class binds only dATP or ATP, since dATP and ATP were the only nucleotides which eluted protein B1 from dATP-Sepharose. These results confirm earlier data obtained by dialysis binding experiments. The eluting concentrations obtained for the different nucleoside triphosphates in experiments with dTTP-Sepharose could be used to calculate unknown dissociation constants for protein B1 -effector binary complexes. This was possible, since a plot of the eluting concentrations vs. known dissociation constants was linear.     

Protein-protein interactions in contact activation of blood coagulation. Binding of high molecular weight kininogen and the 5-(iodoacetamido) fluorescein-labeled kininogen light chain to prekallikrein, kallikrein, and the separated kallikrein heavy and light chains

Binding of the 5-(iodoacetamido)fluorescein (IAF)-labeled high molecular weight (HMW) kininogen light chain to prekallikrein and D-Phe-Phe-Arg-CH2Cl-inactivated kallikrein was monitored by a 0.040 +/- 0.002 increase in fluorescence anisotropy. Indistinguishable average dissociation constants and stoichiometries of 14 +/- 3 nM and 1.1 +/- 0.1 mol of prekallikrein/mol of IAF-light chain and 17 +/- 3 nM and 0.9 +/- 0.1 mol of kallikrein/mol of IAF-light chain were determined for these interactions at pH 7.4, mu 0.14 and 22 degrees C. Prekallikrein which had been reduced and alkylated in 6 M guanidine HCl lost the ability to increase the fluorescence anisotropy of the IAF-kininogen light chain, suggesting that the native tertiary structure was required for tight binding. The kallikrein heavy and light chains were separated on the basis of the affinity of the heavy chain for HMW-kininogen-Sepharose, after mild reduction and alkylation of kallikrein under nondenaturing conditions. Under these conditions, alkylation with iodo [14C]acetamide demonstrated that only limited chemical modification had occurred. Binding of the IAF-kininogen light chain to the isolated alkylated kallikrein heavy chain, when compared to prekallikrein and kallikrein, was characterized by an indistinguishable increase in fluorescence anisotropy, average dissociation constant of 14 +/- 3 nM, and stoichiometry of 1.2 +/- 0.1 mol of kallikrein heavy chain/mol of IAF-light chain. In contrast, no binding of the D-Phe-Phe-Arg-CH2Cl-inactivated kallikrein light chain was detected at concentrations up to 500 nM. Furthermore, 300 nM kallikrein light chain did not affect IAF-kininogen light chain binding to prekallikrein, kallikrein, or the kallikrein heavy chain. The binding of monomeric single chain HMW-kininogen to prekallikrein, kallikrein, and the kallikrein heavy and light chains was studied using the IAF-kininogen light chain as a probe. Analysis of the competitive binding of HMW-kininogen gave average dissociation constants and stoichiometries of 12 +/- 2 nM and 1.2 +/- 0.1 mol of prekallikrein/mol of HMW-kininogen, 15 +/- 2 nM and 1.3 +/- 0.1 mol of kallikrein/mol of HMW-kininogen, 14 +/- 3 nM and 1.4 +/- 0.2 mol of kallikrein heavy chain/mol of HMW-kininogen, and no detectable effect of 300 nM kallikrein light chain on these interactions. We conclude that a specific, nonenzymatic interaction between sites located exclusively on the light chain of HMW-kininogen and the heavy chain of kallikrein or prekallikrein is responsible for the formation of 1:1 noncovalent complexes between these proteins.     

Thermodynamic and kinetic studies on the mechanism of binding of methylumbelliferyl glycosides to jacalin.

The binding of Artocarpus integrifolia lectin (jacalin) to 4-methylumbelliferyl (Meumb)-glycosides, Gal alpha Meumb, Gal beta Meumb, GalNAc alpha Meumb, GalNAc beta-Meumb, and Gal beta 3GalNAc beta Meumb was examined by extrinsic fluorescence quenching titration and stopped flow spectrofluorimetry. The binding was characterized by 100% quenching of fluorescence of Meumb-glycosides. Their association constants range from 2.0 x 10(4) to 1.58 x 10(6) M-1 at 15 degrees C. Entropic contribution is the major stabilizing force for avid binding of Meumb-glycosides indicating the existence of a hydrophobic site that is complementary to their methylumbelliferyl group. The second order association rate constants for interaction of these sugars with lectin at 15 degrees C vary from 8.8 x 10(5) to 3.24 x 10(6) M-1 S-1, at pH 7.2. The first order dissociation rate constants range from 2.30 to 43.0 S-1 at 15 degrees C. Despite the differences in their association rate constants, the overall values of association constants for these saccharides are determined by their dissociation rate constants. The second order rate constant for the association of Meumb-glycosides follows a pattern consistent with the magnitude of the activation energies involved therin. Activation parameters for association of all ligands illustrate that the origin of the barrier between binding of jacalin to Meumb-glycosides is entropic, and the enthalpic contribution is small. A correlation between these parameters and the structure of the ligands on the association rates underscores the importance of steric factors in determining protein saccharide recognitions.     

Interaction of a fluorescent N-dansylaziridine derivative of troponin I with calmodulin in the absence and presence of calcium

Rabbit skeletal muscle troponin I was covalently labeled with N-dansylaziridine, resulting in a fluorescent labeled protein. This derivative (DANZTnI) and native troponin I (TnI) inhibited calmodulin (CaM) stimulation of bovine heart Ca2+-sensitive cyclic nucleodite phosphodiesterase with identical inhibition constants. Association of DANZTnI with calmodulin was monitored directly by changes in flourescence intensity in the presence of Ca2+ and by changes in fluorescence anisotropy in the absence of Ca2+. Quantitation of the affinity of calmodulin for calmodulin-binding proteins in both the presence and absence of Ca2+ is necessary for prediction of the extent of interaction of both Ca2+ and calmodulin-binding proteins with calmodulin in vivo. The dissociation constants for the DANZTnI-calmodulin-l4Ca2+ and DANZTnI-calmodulin complexes were 20 nM and 70 micrometers, respectively. These dissociation constants define a free energy coupling of-4.84 kcal/mol of troponin I for binding of Ca2+ and troponin I to calmodulin. The Ca2+ dependence for troponin I-calmodulin complex formation predicted from these experimentally determined parameters was closely approximated by the Ca2+ dependence for complex formation between troponin I and fluorescent 5-[[[(iodoacetyl)amino]ethyl]-amino]-1-napthalenesulfonic acid derivatized calmodulin as determined by fluorescence anisotropy. Complex formation occurred over a relatively narrow range of Ca2+ concentration, indicative of positive heterotropic cooperativity for Ca2+ and troponin I binding to calmodulin.     

Circular dichroism and hydrodynamic measurements of ternary protein--two ligand systems: serum albumin-bilirubin-drug or alcohol.

The effects of various ligands on bilirubin-serum albumin complexes in aqueous solution were investigated at pH 7.4 and 27 °C by circular dichroism (CD) measurements. The ligands included various penicillins, benzoic acid derivatives, and various lower aliphatic alcohols, using a molar excess of charcoal-treated human or bovine serum albumin with respect to bilirubin. In all cases investigated, significant changes in the visible-range CD spectra of the bilirubin-serum albumin complexes occurred within a certain range of added ligand concentrations. For several such ligand systems, analogous CD effects could be measured on both diluted and undiluted human blood serum or plasma. For part of the isolated albumin-ligand systems, significant dissociation of the bilirubin from the albumin was demonstrated by electrophoretic and analytical ultracentrifugation measurements, while other systems did not reveal measurable dissociation under the conditions used, indicating the formation of a ternary complex. A scheme of equilibria among all complex components is proposed, which includes both dissociation of the bilirubin and ternary complex formation in which the bilirubin conformation appears to be modified. At least two different sets of binding sites (competitive and noncompetitive) for added ligands are assumed. Values of apparent parameters describing the formation of ternary complexes from the bilirubin-albumin complex are estimated for a number of systems. Some relationships between the chemical structure of a ligand and its effect on the bilirubin-serum albumin complex are deduced. The relevance of the results obtained for the isolated protein-ligand complexes with respect to in vivo conditions is evaluated.