Showing papers on "Cooperativity published in 1988"

Determination and characterization of a cannabinoid receptor in rat brain.

Abstract: The determination and characterization of a cannabinoid receptor from brain are reported. A biologically active bicyclic cannabinoid analgetic CP-55,940 was tritium-labeled to high specific activity. Conditions for binding to rat brain P2 membranes and synaptosomes were established. The pH optimum was between 7 and 8, and specific binding could be eliminated by heating the membranes to 60 degrees. Binding to the P2 membranes was linear within the range of 10 to 50 micrograms of protein/ml. Specific binding (defined as total binding displaced by 1 microM delta 9-tetrahydrocannabinol (delta 9-THC) or 100 nM desacetyllevonantradol) was saturable. The Kd determined from Scatchard analysis was 133 pM, and the Bmax for rat cortical P2 membranes was 1.85 pmol/mg of protein. The Hill coefficient for [3H]CP-55,940 approximated 1, indicating that, under the conditions of assay, a single class of binding sites was determined that did not exhibit cooperativity. The binding was rapid (kon approximately 2.6 x 10(-4) pM-1 min-1) and reversible (Koff approximately 0.016 min-1) and (koff' greater than 0.06 min-1). The two Kd values estimated from the kinetic constants approximately 55 pM and exceeded 200 pM, respectively. The binding of the agonist ligand [3H]CP-55,940 was decreased by the nonhydrolyzable GTP analog guanylylimidodiphosphate. The guanine nucleotide induced a more rapid dissociation of the ligand from the binding site, consistent with an allosteric regulation of the putative receptor by a G protein. The binding was also sensitive to MgCl2 and CaCl2. Binding of [3H]CP-55,940 was displaced by cannabinoid drugs in the following order of potency: CP-55,940 greater than or equal to desacetyllevonantradol greater than 11-OH-delta 9-THC = delta 9-THC greater than cannabinol. Cannabidiol and cannabigerol displaced [3H]CP-55,940 by less than 50% at 1 microM concentrations. The (-)-isomer of CP-55,940 displaced with 50-fold greater potency than the (+)-isomer. This pharmacology is comparable to both the inhibition of adenylate cyclase in vitro and the analgetic activity of these compounds in vivo. The criteria for a high affinity, stereoselective, pharmacologically distinct cannabinoid receptor in brain tissue have been fulfilled.

Photophysics and reactivity of heme proteins: a femtosecond absorption study of hemoglobin, myoglobin, and protoheme

Abstract: On the basis of our time-resolved absorption measurements of hemoglobin (Hb), myoglobin (Mb), and protoheme (PTH), either unligated or ligated with CO, O2, or NO, we propose a description of the photophysics of heme proteins that encompasses their photodissociation, the origin and fate of the observed short-lived transients, and the appearance of the ground-state, unligated heme proteins. Two distinct species are formed upon ligand photodissociation, which occurs in less than 50 fs. We assign these species to excited states of the unligated heme and label them (for the case of hemoglobin) as Hb*I and Hb*II. We suggest that Hb*I is already at least partially domed and has a spin state of at least S = 1. Hb*I decays in 300 fs to the ground-state unligated heme species, which we consider to be S = 2 and at least partially domed. The population of Hb*II varies with the ligand. It is more significant when the ligand is O2 or NO than when the ligand is CO. The similarities of the picosecond and femtosecond bleaching and absorption kinetics of HbCO with those of PTHCO (and of HbNO with those of PTHNO) indicate that in this time domain the importance of steric features of the protein are less important than the nature of the ligand itself in the geminate recombination process as well as in the relative amounts of the two heme excited states created. It is suggested that the quantum yield of ligand photodissociation is unity whether the ligand is O2, NO, or CO. The low yield of photodissociated heme-O2 or heme-NO compounds as measured on the microsecond time scale is thus attributed to a fast (2.5 ps) recombination of O2 or NO with Hb*II. We discuss geminate recombination measurements of cyanomet hybrid hemoglobins with NO and consider these results in terms of alpha and beta subunit heterogeneity. The first picosecond transient absorption spectra of cyanomet-CO hybrid hemoglobins are presented and are compared with the spectra of other heme compounds. The superimposability of the transient spectra on the equilibrium spectra of heme compounds that exhibit minimal or no cooperativity is noted and is compared with the case of cooperative systems where the transient spectra are distorted with respect to the equilibrium spectra. This distortion is interpreted in terms of an interaction of a domed heme with the F helix.

Estimation of the affinities of allosteric ligands using radioligand binding and pharmacological null methods.

Abstract: The theoretical basis for using radioligand binding and pharmacological techniques to estimate the dissociation constants of drugs which interact allosterically with receptors is described. This theory predicts that an allosteric ligand changes the affinity of another ligand which binds at the primary recognition site on the receptor complex without affecting the binding capacity of the primary ligand. The magnitude of this effect depends on the amount of cooperativity (positive or negative) between the binding of ligands at the allosteric and primary recognition sites. It is possible to estimate the dissociation constant of an allosteric ligand by measuring its effect on the binding of a radioligand at a fixed concentration. In this situation, the dissociation constant of the allosteric ligand can be calculated from the concentration of ligand which causes half of its maximal effect on radioligand binding. The effects of an allosteric ligand on the pharmacological responses to an agonist can be attributed to changes in affinity and intrinsic efficacy of the agonist-receptor complex. If the agonist used in the pharmacological experiments has a large receptor reserve, or if the allosteric ligand only influences the affinity of the agonist, then the dissociation constant of the allosteric ligand can be calculated from the results of experiments in which the concentration of agonist required for half-maximal response (EC50) is measured in the presence of various concentrations of the allosteric ligand. If the agonist used in the pharmacological experiments is a partial agonist with little receptor reserve, then the shift in the EC50 of the agonist caused by the allosteric ligand may be dependent on the affinity of the agonist.

Cooperativity of the glucocorticoid receptor and the CACCC-box binding factor.

Abstract: Glucocorticoid receptor binding sites (GRE) are often tightly clustered with other transcription factor binding sequences. Examples of this occur upstream of the genes for chicken lysozyme and human metallothionein IIA (ref. 3), in several retroviral LTRs and upstream of the rat tryptophan oxygenase (TO) gene. In the TO gene, sequences immediately upstream of a glucocorticoid receptor binding site are required for steroid induction and contain a CACCC-box identical to that found in the beta globin gene. Here we demonstrate specific binding to this TO-CACCC element and show that it will also act cooperatively with a MMTV glucocorticoid receptor binding site. The response to dexamethasone is independent of the order and relative orientation of these elements but does depend on their precise spacing. Optimal induction occurs at a periodicity of approximately 10 base pairs (bp) indicating a requirement for stereospecific alignment. Binding to the CACCC box, however, is not affected by its distance from the glucocorticoid receptor site. We conclude that the observed cooperativity is mediated by protein:protein interactions and does not depend on cooperative DNA binding.

A peptide model of a protein folding intermediate

Abstract: It is difficult to determine the structures of protein folding intermediates because folding is a highly cooperative process. A disulphide-bonded peptide pair, designed to mimic the first crucial intermediate in the folding of bovine pancreatic trypsin inhibitor, contains secondary and tertiary structure similar to that found in the native protein. Peptide models like this circumvent the problem of cooperativity and permit characterization of structures of folding intermediates.

Equilibrium binding of Escherichia coli single-strand binding protein to single-stranded nucleic acids in the (SSB)65 binding mode. Cation and anion effects and polynucleotide specificity.

Abstract: The Escherichia coli single-strand binding (SSB) protein binds single-stranded (ss) nucleic acids in at least four distinct binding modes depending on the salt conditions [Lohman, T. M., & Overman, L. B. (1985) J. Biol. Chem. 260, 3594; Bujalowski, W., & Lohman, T. M. (1986) Biochemistry 25, 7799]. Equilibrium binding constants for the interaction of the E. coli SSB protein with poly(A), poly(U), poly(dA), and poly(dT) have been measured over a range of monovalent salt concentrations and types under conditions which favor only the high site size, (SSB)65 binding mode, which covers 65 nucleotides per SSB tetramer. The binding isotherms are analyzed by using a statistical thermodynamic model ("tetramer/octamer" model) that assumes cooperative binding of SSB is limited to the formation of octamers [Bujalowski, W., & Lohman, T. M. (1987) J. Mol. Biol. 195, 897] rather than the indefinite clustering of tetramers. The dependence of the intrinsic association equilibrium constant, Kobsd, and cooperativity parameter, omegoT/O, on salt concentration has been determined by titrations which monitor the fluorescence quenching of the SSB protein upon complex formation. In the (SSB)65 binding mode, SSB binds with only moderate cooperativity to ss nucleic acids [Lohman, T. M., Overman, L. B., & Datta, S. (1986) J. Mol. Biol. 187, 603]. The cooperativity parameter derived from the tetramer/octamer model, which represents the equilibrium constant for formation of a nucleic acid bound SSB octamer from two nucleic acid bound tetramers, has a value of omegaT/O = 410 +/- 120 and is independent of salt concentration and type for poly(dA), poly(U), and poly(A) (25 degrees C, pH 8.1). However, Kobsd decreases steeply with increasing salt concentration, such that alpha log Kobsd/alpha log [NaCl] = -7.4 +/- 0.5 for poly(U), -6.1 +/- 0.6 for poly(dA), and -6.2 +/- 0.3 for poly(A) (25.0 degrees C, pH 8.1). The SSB-poly(dT) affinity is too high to measure in buffers containing even 5 M NaCl; however, in 1.8-2.5 M NaBr, we measure alpha log Kobsd/alpha log [NaBr] = -5.7 +/- 0.7, with a lower value of omega T/O = 130 +/- 70. The polynucleotide specificity of the (SSB)65 binding mode (0.20 M NaCl, 25.0 degrees C, pH 8.1) is Kobsd(dT) greater than Kobsd(dC) much greater than Kobsd(ss M13 DNA) greater than Kobsd(I) greater than Kobsd(U) = 8Kobsd(dA) = 87Kobsd(A) much greater than Kobsd(C).(ABSTRACT TRUNCATED AT 400 WORDS)

Escherichia coli aspartate transcarbamylase: the relation between structure and function

Abstract: The x-ray structures of the allosteric enzyme aspartate transcarbamylase from Escherichia coli have been solved and refined for both allosteric forms. The T form was determined in the presence of the heterotropic inhibitor cytidine triphosphate, CTP, while the R form was determined in the presence of the bisubstrate analog N-phosphonacetyl-L-aspartate. These two x-ray structures provide the starting point for an understanding of how allosteric enzymes are able to control the rates of metabolic pathways. Insights into the mechanisms of both catalysis and homotropic cooperativity have been obtained by using site-directed mutagenesis to probe residues thought to be critical to the function of the enzyme based on these x-ray structures.

The role of protein surface charges in ion binding

Abstract: Protein engineering is a means of probing the role of electrostatic interactions in protein functions; this elegant technique has been applied to the elucidation of electrostatic effects in enzyme catalysis. Here we show how the use of mutant proteins allows the determination of the contributions of individual charges to the free energy of ion binding to proteins. We have investigated the importance of three negatively charged side chains in the binding of Ca2+ to bovine calbindin D9K (ref.2): these are clustered around the calcium sites but are not directly involved as ligands. Each of these charges is found to contribute approximately 7 kJ mol-1 to the free energy of binding of two Ca2+ ions and to affect the cooperativity of Ca2+ binding. The influence of surface charges on ion binding to proteins may be more common than generally supposed and could have important consequences for protein function.

Assembly of the 30S subunit from Escherichia coli ribosomes occurs via two assembly domains which are initiated by S4 and S7.

Abstract: A protein which initiates assembly of ribosomes is defined as a protein which binds to the respective rRNA without cooperativity (i.e., without the help of other proteins) during the onset of assembly and is essential for the formation of active ribosomal subunits. The number of proteins binding without cooperativity was determined by monitoring the reconstitution output of active particles at various inputs of 16S rRNA, in the present of constant amounts of 30S-derived proteins (TP30): This showed that only two of the proteins of the 30S subunit are assembly-initiator proteins. These two proteins are still present on a LiCl core particle comprising 16S rRNA and 12 proteins (including minor proteins). The 12 proteins were isolated, and a series of reconstitution experiments at various levels of rRNA excess demonstrated that S4 and S7 are the initiator proteins. Pulse-chase experiments performed during the early assembly with /sup 14/C- and /sup 3/H-labeled TP30 and the determination of the /sup 14/C//sup 3/H ratio of the individual proteins within the assembled particles revealed a bilobal structure of the 30S assembly: A group of six proteins headed by S4 (namely, S4, S20, S16, S15, S6, and S18) resisted the chasing most efficiently (S4 assembly domain). Nonemore » of the proteins depending on S7 during assembly were found in this group but rather in a second group with intermediate chasing stability (S7 assembly domain; consisting of S7, S9, (S8), S19, and S3). A number of proteins could be fully chased during the early assembly and therefore represent late assembly proteins (S10, S5, S13, S2, S21, S1). These findings fit well with the 30S assembly map. These data, together with the assembly map, imply that S8 and S5 play an important role in the interconnection of the two assembly domains.« less

A possible model for the concerted allosteric transition in Escherichia coli aspartate transcarbamylase as deduced from site-directed mutagenesis studies.

Abstract: Aspartate transcarbamylase is stabilized in a low-affinity-low-activity state exhibiting no cooperativity by selective perturbation of the Glu-50-Arg-167 and Glu-50-Arg-234 interdomain salt bridges. Similarly, a high-affinity-high-activity state of the enzyme, retaining a significant amount of cooperativity, is obtained by perturbation of the interaction between Tyr-240 and Asp-271. In this work, we show that the rupture of the link between Tyr-240 and Asp-271 in the enzyme already lacking the interdomain salt bridges regenerates the homotropic cooperative interactions between the catalytic sites and substantially increases the activity and affinity of the enzyme for aspartate. These results suggest a possible relationship between these two sets of interactions for the establishment of the cooperative behavior of the enzyme. Another mutation, Glu-239 to Gln, introduced to perturb the Glu-239-Lys-164 and Glu-239-Tyr-165 interactions between the two catalytic subunits, is sufficient to "lock" the enzyme in the R state. These observations emphasize the importance of the interactions at the interface between the catalytic trimers in maintaining the T state of the enzyme and shed light on the role played by this pathway in the communication of homotropic cooperativity between the different sites. A model including all these findings, as well as the interactions stabilizing the T state or the R state in the presence of the natural substrates, is proposed.(ABSTRACT TRUNCATED AT 250 WORDS)

Relationship between domain closure and binding, catalysis, and regulation in Escherichia coli aspartate transcarbamylase.

Abstract: Previous evidence, from both crystallographic and biochemical studies, has indicated that profound tertiary and quaternary changes in the structure of Escherichia coli aspartate transcarbamylase occur upon the binding of the bisubstrate analogue N-(phosphonoacetyl)-L-aspartate (PALA). In particular, within a single catalytic polypeptide chain, the aspartate binding domain relocates closer to the carbamyl phosphate binding domain, thereby resulting in a major reorganization of the interface between the two domains. Among the new interactions, salt bridges between Glu-50 and both Arg-167 and Arg-234 are formed. In the present study, site-directed mutagenesis is used to replace Glu-50 by glutamine in the catalytic chain. The Michaelis constant for aspartate of the mutant catalytic subunit is about 10-fold higher and the turnover number 10-fold lower than their respective counterparts in the wild-type catalytic subunit, whereas the dissociation constant for carbamyl phosphate is almost unchanged. For the holoenzyme, this substitution results in an 8-fold decrease in the specific activity, a 20-fold increase in the aspartate concentration that gives half of the maximal velocity, and a loss of cooperativity for both substrates. However, the mutant enzyme is not "frozen" in a low-affinity-low-activity conformation since PALA stimulates the activity severalfold and induces an increase in the sulfhydryl reactivity analogous to that of the wild-type enzyme. Together these results indicate that the stabilization of the aspartate binding domain near the carbamyl phosphate binding domain, through specific interdomain bridging interactions, is necessary for the high-affinity-high-activity configuration of the active site.(ABSTRACT TRUNCATED AT 250 WORDS)

Differences in the binding of H1 variants to DNA. Cooperativity and linker-length related distribution.

Abstract: A study of the complexes formed between short linear DNA and three H1 variants, a typical somatic H1, and the extreme variants H5, from chicken erythrocytes, and spH1 from sea urchin sperm, has revealed differences between H1, H5 and spH1 that have implications for chromatin structure and folding. 1 All three histones bind cooperatively to DNA in 35 mM NaCl forming similar, but not identical, rod-like complexes. With sufficiently long DNA the complexes may be circular, circles forming more easily with H5 and spH1 than with H1. 2 The binding of H5 and spH1 to DNA is cooperative even in 5 mM NaCl, resulting in well-defined thin filaments that appear to contain two DNA molecules bridged by histone molecules. In contrast, H1 binds distributively over all the DNA molecules in 5 mM NaCl, but forms short stretches similar in appearance to the thin filaments formed with H5 and spH1. Rods appear to arise from the intertwining of regular thin filaments containing cooperatively bound histone molecules on raising the NaCl concentration to 35 mM. 3 The compositions of the rods correspond to one histone molecule for about every 47 bp (H1), 81 bp (H5) and 112 bp (spH1), suggesting average spacings of 24 bp (H1), 41 bp (H5) and 56 bp (spH1) in the component thin (double) filaments. Strikingly, these values are proportional to the linker lengths of the chromatins in which the particular H1 variant is the main or sole H1.

The effect of quaternary structure on the kinetics of conformational changes and nanosecond geminate rebinding of carbon monoxide to hemoglobin

Abstract: To determine the effect of quaternary structure on the individual kinetic steps in the binding of carbon monoxide to the alpha subunit of hemoglobin, time-resolved absorption spectra were measured after photodissociation of carbon monoxide from a hemoglobin tetramer in which cobalt was substituted for iron in the beta subunits. Cobalt porphyrins do not bind carbon monoxide. Spectra were measured in the Soret region at room temperature after time delays that varied from a few nanoseconds to the completion of ligand rebinding at about 100 ms. The results show that the liganded molecule, alpha(Fe-CO)2 beta(Co)2, is in the R state, but can be almost completely switched into the T state by the allosteric effectors inositol hexaphosphate and bezafibrate. The geminate yield, which is the probability that the ligand rebinds to the heme from within the protein, is found to be 40% for the R state and less than 1% for the T state. According to the simplest kinetic model, these results indicate that carbon monoxide enters the protein in the R and T quaternary conformations at the same rate, and that the 60-fold decrease in the overall binding rate, of carbon monoxide to the alpha subunit in the T state compared to the R state is almost completely accounted for by the decreased probability of binding after the ligand has entered the protein. The results further suggest that the low probability for the T state results from a decreased binding rate to the heme and not from an increased rate of return of the ligand to the solvent.

Analysis of proton release in oxygen binding by hemoglobin: implications for the cooperative mechanism.

Abstract: The relationship in hemoglobin between cooperativity (dependence of the Hill constant on pH0 and the Bohr effect (dependence of the mean oxygen affinity on pH) can be described by a statistical thermodynamic model [Szabo, A., & Karplus, M. (1972) J. Mol. Biol. 72, 163-197; Lee, A., & Karplus, M. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 7055-759]. In this model, salt bridges and other interactions serve to couple tertiary and quaternary structural changes. To test and refine the model, it is applied to the analysis of the pH dependence of the tetramer Adair constants corrected for statistical factors (K4i', i = 1-4). Attention is focused on the proton release of the first (delta H1+ = alpha log K41'/alpha pH) and last (delta H4+ = alpha log K44'/alpha pH) oxygenation steps, where K4i' are the Adair constants corrected for statistical factors. Measurements of delta H1+ and delta H4+ under carefully controlled conditions are reported, and good agreement between the model calculation and these experimental results is obtained. The salt bridges are found to be partially coupled to the ligation state in the deoxy quaternary structure; it is shown that a Monod-Wyman-Changeux-type model, in which the salt bridges are coupled only to quaternary structural change, is inconsistent with the data for delta H1. The significance of the present analysis for an evaluation of the Perutz mechanism [Perutz, M.F. (1970) Nature (London) 228, 726-734, 734-739] and other models for hemoglobin cooperativity is discussed.

Evidence for cooperativity between E2 binding sites in E2 trans-regulation of bovine papillomavirus type 1.

Abstract: The long control region of bovine papillomavirus type 1 (BPV-1) can function in an orientation- and position-independent manner as an E2-dependent enhancer. Dissection of the long control region has revealed two E2-responsive elements, E2RE1 and E2RE2, which map, respectively, between nucleotides 7611 and 7806 and between nucleotides 7200 and 7386 of the BPV-1 genome. In this study, we have carried out a detailed analysis of E2RE1, which has previously been shown to be involved in the regulation of the BPV-1 promoters P89 and P7940. One characteristic of E2RE1 is the presence of a pair of ACCN6GGT motifs (E2 binding sites) at each end of the element. To determine the contribution of these sites, as well as other sequences within E2RE1, to enhancer function, specific mutations and deletions were generated by oligonucleotide reconstruction. The functional analysis of these mutations confirmed that a pair of E2 binding sites was essential for E2-dependent enhancer activity but also indicated that cooperativity between the motifs at each end of E2RE1 creates a highly responsive element. Isolated ACCN6GGT motif pairs could also act as E2-dependent enhancers but at a significantly reduced level in comparison to the intact element. The sequences between the E2 binding sites in E2RE1 were not required for enhancer function and could actually block the enhancer activity of an isolated pair of E2 binding sites when positioned between the binding sites and the enhancer-deleted simian virus 40 early promoter.

Binding capacity: cooperativity and buffering in biopolymers.

Abstract: The group of linkage potentials resulting from the energy of a physicochemical system expressed per mol of a reference component, say a polyfunctional macromolecule, leads to the concept of binding capacity. This concept applies equally to both chemical and physical ligands and opens the way to consideration of higher-order linkage relationships. It provides a means of exploring the consequences of thermodynamic stability on generalized binding phenomena in biopolymers.

Modulation of the bilayer to hexagonal phase transition and solvation of phosphatidylethanolamines in aqueous salt solutions.

Abstract: Several salts affect the temperature of the bilayer to hexagonal phase transition of phosphatidylethanolamines. Their effects are dependent on the anion as well as the cation of the salt. Salt effects on this transition can be explained by preferential hydration and ion binding. Those salts which are excluded from the solvation sphere of the membrane promote hexagonal phase formation. For example, Na2SO4 promotes preferential hydration and is a hexagonal phase promoter while NaSCN does not do this and is a bilayer stabilizer. Unlike amphiphiles and hydrocarbons, salts can shift the bilayer to hexagonal phase transition temperature without altering the cooperativity of the transition. The effect of these salts on the gel to liquid-crystal transition is opposite to their effect on the bilayer to hexagonal phase transition. We also find that MnCl2 markedly raises the gel to liquid-crystal transition temperature. This effect is due to binding of the cation to the membrane surface. The effect is reduced with MnSO4 because of preferential hydration. Our results demonstrate that the nature of the anion as well as the cation can alter the effect of salts on lipid phase transition properties. The observed effects can be explained as resulting from preferential hydration and ion binding.

Phase variation in Salmonella: analysis of Hin recombinase and hix recombination site interaction in vivo

Abstract: The bacteriophage P22-based challenge phase selection was used to characterize the binding of Salmonella Hin recombinase to the wild-type hixL and hixR recombination sites, as well as to mutant and synthetic hix sequences in vivo. Hin recombinase binds to the hixL or hixR recombination sites and represses transcription from an upstream promoter in the challenge phage system. Hin-mediated repression results from Hin associating into multimers either prior to binding or during the binding process at the hix operator sites (cooperativity). The ability of Hin multimers to repress transcription is eliminated when the hix 13-bp half-sites are rotated to opposite sides of the DNA helix by inserting 4 bp between them. Insertion of 1 bp between half-sites reduces overall repression. Hin also binds one of the hixL half-sites to repress transcription, but only when high levels of Hin protein are present in the cell. Mutations have been identified in the hix sites that impair Hin binding. Five of the 26 bp in the hix sites are critical; sites with base-pair substitutions at these five positions show greatly reduced binding. Three additional base pairs make minor contributions to binding. These results are consistent with the results of binding studies between Hin and the hix sites in vitro.

Interaction of divalent cations with polyuronates

Abstract: The interaction of some divalent cations (Ca2+, Cu2+, Pb2+, Zn2+ and Cd2+) with two polyuronates (alginate and polygalacturonate) has been studied by thermodynamic and structural methods. From the thermodynamic results, the enthalpy of interaction is claimed to reveal the changes in the conformation and/or association of polymeric chains, while the dilatometric results are related with the solvent release due to ion binding. The degree of cooperativity of the ion-binding process (with Ca and Pb) is evidenced by the calorimetric and dilatometric data and, more quantitatively, by the Scatchard plot of the single-ion activity data (with Cu). Theoretical evaluation of the electrostatic energy change accompanying the process of mixing polyuronates with ions and/or of the conformational energy of the polysaccharide is carried out to discriminate the cases in which the binding process is complicated by other effects (chain aggregation or conformational change). Further structural information is obtained by studying the perturbation on the circular dichroic bands of the chromophore arising from the binding process.