Temperature dependence of the binding of mu, delta and kappa agonists to the opiate receptors in guinea-pig brain

Simplified Method for Kinetic and Thermodynamic Screening of Cardiotonic Steroids through the K+-Dependent Phosphatase Activity of Na+/K+-ATPase with Chromogenic pNPP Substrate

The antitumor effect of cardiotonic steroids (CTS) has stimulated the search for new methods to evaluate both kinetic and thermodynamic aspects of their binding to Na+/K+-ATPase (IUBMB Enzyme Nomenclature). We propose a real-time assay based on a chromogenic substrate for phosphatase activity (pNPPase activity), using only two concentrations with an inhibitory progression curve, to obtain the association rate (kon ), dissociation rate (koff ), and equilibrium (Ki ) constants of CTS for the structure-kinetics relationship in drug screening. We show that changing conditions (from ATPase to pNPPase activity) resulted in an increase of Ki of the cardenolides digitoxigenin, essentially due to a reduction of kon In contrast, the Ki of the structurally related bufadienolide bufalin increased much less due to the reduction of its koff partially compensating the decrease of its kon When evaluating the kinetics of 15 natural and semisynthetic CTS, we observed that both kon and koff correlated with Ki (Spearman test), suggesting that differences in potency depend on variations of both kon and koff A rhamnose in C3 of the steroidal nucleus enhanced the inhibitory potency by a reduction of koff rather than an increase of kon Raising the temperature did not alter the koff of digitoxin, generating a ΔH‡ (koff ) of -10.4 ± 4.3 kJ/mol, suggesting a complex dissociation mechanism. Based on a simple and inexpensive methodology, we determined the values of kon , koff , and Ki of the CTS and provided original kinetics and thermodynamics differences between CTS that could help the design of new compounds. SIGNIFICANCE STATEMENT: This study describes a fast, simple, and cost-effective method for the measurement of phosphatase pNPPase activity enabling structure-kinetics relationships of Na+/K+-ATPase inhibitors, which are important compounds due to their antitumor effect and endogenous role. Using 15 compounds, some of them original, this study was able to delineate the kinetics and/or thermodynamics differences due to the type of sugar and lactone ring present in the steroid structure.

Nociceptin receptor binding in mouse forebrain membranes: thermodynamic characteristics and structure activity relationships

The present study describes the labelling of the nociceptin (NC) receptor, ORL1, in mouse forebrain membranes with a new ligand partially protected from metabolic degradation at the C-terminal; the ligand, [3H]-NC-NH2, has a specific activity of 24.5 Ci mmol(-1). Saturation experiments revealed a single class of binding sites with a KD value of 0.55 nM and Bmax of 94 fmol mg(-1) of protein. Non specific binding was 30% of total binding. Kinetic binding studies yielded the following rate constants: Kobs = 0.104 min(-1); K1 =0.034 min(-1): T1/2=20 min; K(+1)=0.07 min nM(-1). Thermodynamic analyses indicated that [3H]-NC-NH2 binding to the mouse ORL1 is totally entropy driven, similar to what has been observed for the labelled agonists to the opioid receptors OP1(delta), OP2(kappa) and OP3(mu). Receptor affinities of several NC fragments and analogues, including the newly discovered ORL-1 receptor antagonist [Phe1psi(CH2-NH)Gly2]NC(1-13)-NH2([F/G]NC(1-13)-NH2), were also evaluated in displacement experiments. The competition curves for these compounds were found to be parallel to that of NC and the following order of potency was determined for NC fragments: NC-OH = NC-NH2-NC(1-13)-NH2 > > NC(1-12)-NH2 > NC(1-13)-OH > > NC(1-11)-NH2, and for NC and NC(1-13)-NH2 analogues: [Tyr1]NC-NH2 > or = [Leu1]NC(1-13)-NH2 > or = [Tyr1]NC(1-13)-NH2 > or = [F/G]NC(1-13)-NH2 > > [Phe3]NC(1-13)-NH2 > [DF/G]NC(1-13)-NH2. Standard opioid receptor ligands (either agonists or antagonists) were unable to displace [3H]-NC-NH2 binding when applied at concentrations up to 10 microM indicating that this new radioligand interacts with a non opioid site, probably the ORL1 receptor.

Apparent thermodynamic parameters of ligand binding to the cloned rat mu-opioid receptor

The apparent thermodynamic parameters of binding of ten ligands to the cloned rat mu-opioid receptor stably expressed in Chinese hamster ovary (CHO) cells were investigated. For every ligand, the Kd or Ki values at 0 degrees C, 12 degrees C, 25 degrees C and 37 degrees C were determined, a van't Hoff plot was generated and deltaH degrees' , deltaS degrees' and -TdeltaS degrees' and deltaG degrees' were calculated. Changes in free energy (deltaG degrees') ranged from -10.35 to -15.65 kcal/mol. The binding of sufentanil, ohmefentanyl, diprenorphine and D-Phe-Cys-Tyr-D-Trp-Arg-Thr-penicillamineThr-NH2 (CTAP) was endothermic (deltaH degrees' > 0) and driven by an increase in entropy (-TdeltaS degrees' = -13.08 to -18.57 kcal/mol). The binding of naltrexone was exothermic (deltaH degrees' = -12.56 kcal/mol) and essentially enthalpy-driven. The binding of morphine, methadone, pentazocine, [D-Ala2, NMePhe4, Gly-ol]enkephalin (DAMGO) and Tyr-Pro-NMePhe-D-Pro-NH2 (PL017) was exothermic (deltaH degrees' = -3.53 to -9.95 kcal/mol) and occurred with an increase in entropy (-TdeltaS degrees' = -2.48 to -7.92 kcal/mol). Plots of enthalpy versus entropy and enthalpy versus free energy were linear, although enthalpy-entropy compensation was not evident. The entropy changes were not correlated with apparent lipophilicity of the compounds. These results suggest that: (1) opioid ligands bind to the mu receptor by specific mechanisms, unrelated to lipid solubility; (2) the mechanism of binding is not universally different for peptide and non-peptide ligands; (3) the nature of binding does not a priori determine intrinsic activity. The results reveal a novel differentiation of opioid ligands into two groups (group 1: ohmefentanyl, sufentanil, diprenorphine, CTAP and PL017; group 2: naltrexone, morphine, methadone, DAMGO, pentazocine), based on two distinct relationships between enthalpy versus free energy of binding, the details of which are yet to be elucidated.

Thermodynamics of ligand binding to the cloned delta-opioid receptor

The goal of this study was to determine the relative contribution of entropy and enthalpy to the free energies of binding to recombinant mouse delta-opioid receptors for the peptide agonist, DPDPE ([D-Pen2,D-Pen5]enkephalin), the peptide antagonist, TIPP(psi) (Tyr-Tic(psi)[CH2NH]Phe-Phe-OH), the nonpeptide agonist, SNC80 ((+)-4-[(alphaR)-alpha-((2S,5R)-4-allyl-2,5-dimethyl-1-piperazinyl )-3-methoxybenzyl]-N,N-diethylbenzamide), and the nonpeptide antagonist, naltrindole. Competitive binding studies were carried out using [3H]naltrindole at 0 degrees C, 12 degrees C, 25 degrees C and 37 degrees C, the affinities calculated and van't Hoff plots constructed for each ligand. The temperature dependence of binding and van't Hoff plots indicated that the entropy contribution is the major component of the free energy, for all four ligands, independent of its activity or chemical nature.

Binding thermodynamics of 5-HT1A receptor ligands

The thermodynamic parameters delta G degree, delta H degree and delta S degree of the binding equilibrium of 15 ligands (eight agonists and seven antagonists) to the 5-HT1A receptor subtype have been determined by affinity measurements carried out on rat cortex membranes (minus striatum) at six different temperatures (0, 10, 20, 25, 30, 35 degrees C), and by van't Hoff plots. Most of the compounds studied are tryptamine, phenylpiperazine and tetralin derivatives. Affinity constants were measured by saturation experiments for the selective 5-HT1A receptor agonist [3H]8-hydroxy-N,N-dipropyl-2-aminotetralin ([3H]8-OH-DPAT) and by inhibition assays of [3H]8-OH-DPAT binding for the other compounds. Scatchard plots were monophasic in the full range of temperatures, indicating a single class of high affinity binding sites. Van't Hoff plots of all ligands were linear in the temperature range investigated (0-30 degrees C or 0-35 degrees C). 5-Hydroxytryptamine (serotonin) and 5-methoxy-tryptamine (mexamine) displayed a positive slope. Experimental data indicate that for 5-HT1A receptor subtype agonists and antagonists are not thermodynamically discriminated. The results are discussed from a quantitative point of view with the aim of obtaining new details on the nature of the forces driving the 5-HT1A binding at a molecular level.

Binding thermodynamics at A1 and A2A adenosine receptors

Only recently the binding equilibrium of a number of ligands at adenosine A1 and A2a receptors has been analyzed from a thermodynamic point of view. This approach presents the advantage, with respect to usual affinity constant measurements, of a greater capability to give information about the molecular mechanisms underlying the binding process. All available data agree in indicating that, for both A1 and A2a receptors, agonist binding of adenosine derivatives was totally entropy-driven, while xanthine antagonist binding was essentially enthalpy-driven. The differences in thermodynamic behaviour of A1 and A2a agonists and antagonists could be interpreted in terms of a simplified general model of drug-receptor interaction, which accounted for the role played by the ribose moiety and N6-substituents of adenosinic drugs in determining both affinity and intrinsic activity properties. In the frame of this model, measurements of thermodynamic parameters of N6-monosubstituted agonists allowed to hypothesize, for the first time, the existence of partial agonists to adenosine A1 receptors, as now confirmed experimentally. All thermodynamic data concerning the interaction of all ligands studied with A1 and A2a receptors are briefly discussed in terms of the enthalpy-entropy compensation phenomenon which appears to be widely determined by the reorganization of solvent molecules in the binding process.

Thermodynamic parameters of opioid binding in the presence and absence of G-protein coupling

We have investigated the thermodynamic parameters of various opioid ligands interacting with their receptors in rat brain membranes. Affinity constants (Ka), enthalpy and entropy values were obtained from homologous displacement experiments performed at 0, 24 and 33 degrees C. It was found that all the opioid agonists tested ([3H]dihydromorphine (DHM) mu alkaloid; [3H]DAMGO mu peptide; [3H]deltorphin-B delta peptide) display endothermic binding accompanied with a large entropy increase, regardless of their chemical structure (alkaloid or peptide), or of their mu or delta receptor selectivity. In contrast, binding of the antagonist naloxone is exothermic, mainly enthalpy driven. Na+ or Mg2+ results only in quantitative changes of the thermodynamic parameters. In the presence of the GTP-analog Gpp(NH)p; or Gpp(NH)p + Na+; or Gpp(NH)p + Na- + Mg2+ the affinity of DHM binding dramatically decreases which might reflect functional uncoupling of the receptor-ligand complex and G-proteins. This altered molecular interactions are also indicated by curvilinear van't Hoff plot and entropy increase. It is concluded that the thermodynamic analysis provides means of determining the underlying driving forces of ligand binding and helps to delineate its mechanism.

Thermodynamics of 5-HT3 receptor binding discriminates agonistic from antagonistic behaviour

Thermodynamic parameters delta G degree, delta H degree and delta S degree of the binding equilibrium of eleven ligands (seven agonists and four antagonists) to the serotonin 5-HT3 receptor subtype have been determined by affinity measurements carried out on rat cortex membranes at six different temperatures (0, 10, 20, 25, 30, 35 degrees C) and van't Hoff plots. Affinity constants were obtained from saturation experiments of [3H]endo-N-(9-methyl-9-azabicyclo[3.3.1]non-3-yl)-1-methyl-1-H-indazole- 3- carboxamide ([3H]BRL 43694, a selective 5-HT3 ligand) or by its displacement in inhibition assays for the other compounds. Van't Hoff plots were essentially linear in the temperature range investigated, showing that the delta Cp degree of the binding equilibrium is nearly zero. Thermodynamic parameters are in the range 18 < or = delta H degree < or = 53 kJ mol-1 and 202 < or = delta S degree < or = 320 J K-1 mol-1 for agonists and -16 < or = delta H degree < or = 0 kJ mol-1 and 70 < or = delta S degree < or = 179 J K-1 mol-1 for antagonists indicating that agonistic binding is totally entropy-driven while antagonistic binding is relatively less entropy- and more enthalpy-driven in the -T delta S degree versus delta H degree plot the thermodynamic data are clearly arranged in separate clusters for agonists and antagonists, which, therefore, turn out to be thermodynamically discriminated. Experimental results are discussed according to the following main points: (i) the approximate linearity of the delta H degree versus delta S degree plot in terms of enthalpy-entropy compensation and (ii) the fact that delta Cp degree approximately equal to 0 for practically all membrane receptors at variance with most reactions involving biomacromolecules in solution. Finally, the phenomenon of thermodynamical discrimination is reviewed and found to occur in five distinct membrane receptorial systems.

Binding thermodynamics of adenosine A2a receptor ligands

The thermodynamic parameters delta G degree, delta H degree, and delta S degree of the binding equilibrium of seven adenosine agonists and five xanthine antagonists binding specifically to adenosine A2a receptors were determined by means of affinity measurements at six different temperatures (0, 10, 20, 25, 30 and 35 degrees) and van't Hoff plots. Affinity constants were measured on rat striatum membranes by saturation experiments for the selective A2a agonist 2-[p-(carboxy-ethyl)-phenethylamino-]5'-(N-ethyl)carboxamidoadenos ine ([3H]CGS 21680) and by inhibition assays of [3H]CGS 21680 binding for all other compounds. Scatchard plots were monophasic in the full range of temperatures, indicating a single class of high affinity binding sites whose receptor density, BMAX, is essentially temperature independent. Van't Hoff plots were linear in the temperature range 0-30 degrees for agonists and 0-35 degrees for antagonists; their thermodynamic parameters fall, respectively, in the ranges 7 < or = delta H degree < or = 50 kJ/mol and 177 < or = delta S degree < or = 278 J K-1 mol-1 and -36 < or = delta H degree < or = -7 kJ/mol and -33 < or = delta S degree < or = 94 J K-1 mol-1, showing that agonist binding is entropy-driven while antagonist binding is enthalpy-driven. The results are compared with those already reported for the binding of the same compounds to rat brain minus striatum adenosine A1 receptors obtained by displacing [3H]CHA as A1 selective radioligand (Borea PA et al., Mol Neuropharmacol 2: 273-281, 1992). The comparison suggests that the two receptors are very similar as far as their binding sites are concerned and possibly philogenetically related. The analysis of thermodynamical data makes it possible to propose an analogical model of drug-receptor interaction which may account for both affinity and intrinsic activity properties.

Thermodynamic analysis of agonist and antagonist binding to the chicken brain melatonin receptor

1. The binding of 2-[125I]-iodomelatonin to chicken brain membranes, and the inhibition of binding by melatonin, N-acetyltryptamine and luzindole, were examined at temperatures between 4 degrees C and 37 degrees C. 2. At all temperatures studied, the binding affinity (Kd or Ki) for 2-[125I]-iodomelatonin, melatonin (both agonists) and, to a lesser extent, N-acetyltryptamine (a partial agonist) was reduced by inclusion of guanosine triphosphate (GTP, 1 mM) in the assay. GTP did not affect the Ki for luzindole, a melatonin receptor antagonist. 3. The maximal density of binding sites (Bmax) was not affected by temperature but the Kd showed a peak at 21 degrees C with lower values at both higher and lower temperatures giving curvilinear van't Hoff plots (lnKA vs l/temperature). 4. Derived changes in entropy (delta S degree) and enthalpy (delta H degree) of binding for all of the melatonin ligands decreased as temperature increased. 5. The affinity, and thus the free energy of binding, delta G degree, of these ligands at the melatonin receptor have identical values at several temperatures yet at these temperatures delta S degree and delta H degree were very different, implying that more than one intermolecular force must be involved in the binding of ligand and receptor. 6. Conceivably, the large positive delta S degree observed at low temperatures, perhaps as a result of hydrophobic interactions, is compensated by a corresponding, but opposite, change in enthalpy at higher temperatures. However, it is not clear what type of binding force(s) would show such a temperature-dependence. 7. These studies suggest that caution must be exercised in the molecular interpretation of derived measures of delta S degree and delta H degree obtained from direct measurements of delta G degree.

Thermodynamic parameters for [D-Pen2,5]enkephalin at delta-opioid receptors in the mouse isolated vas deferens

Dissociation constants (KA) for [D-Pen2,5]enkephalin (DPDPE) inhibition of the electrically evoked twitch of the mouse isolated vas deferens preparation (MVD) were calculated at five temperatures (25, 30, 34, 37 and 40 degrees C). These values were determined from the equiactive concentrations obtained before (A) and after (A') partial irreversible blockade of a fraction of the receptor population by beta-chlornaltrexamine (beta-CNA) plotted as (1/A') where KA = (slope -1)/intercept. The values of KA tended to increase (approximately doubled) over this temperature range, indicating that the affinity of DPDPE for the opioid delta receptor is an inverse function of temperature. From these results, thermodynamic parameters were calculated from a Van't Hoff plot of 1n(KA) against 1/T. The relative magnitudes of the change in enthalpy (delta Ho' = -6.67 kcal mol-1), the change in entropy (delta So' = +0.009 kcal mol-1 degrees K-1) and the change in free energy (delta Go' = -9.43 kcal mol-1) suggest that the interaction between DPDPE and the delta-opioid receptor in MVD is an exothermic exergonic reaction, predominantly enthalpy-driven and results in an increase in the entropy of the system.

Effects of sodium and temperature on naloxone binding in brain tissues of a urodele amphibian

1. Partially purified brain membranes obtained from male rough-skinned newts (Taricha granulosa) were used to determine the effects of NaCl and temperature on the specific binding of the opioid receptor antagonist [3H]naloxone. 2. The addition of NaCl to the incubation medium at concentrations up to 400 mM produced a dose-related increase of the specific binding of [3H]naloxone. 3. The addition of other salts to the incubation medium had less pronounced effects: KCl and MgCl2 slightly increased and decreased, respectively, the specific binding of naloxone, and CaCl2 had no effect. 4. Results of an equilibrium saturation experiment showed that the addition of 200 mM NaCl resulted in over a 10-fold increase in the number of high affinity (KD = 0.61 nM) binding sites for naloxone, with no changes in the number of low affinity (KD = 21.8 nM) binding sites. 5. Changes in NaCl concentrations did not significantly affect either dissociation constant. 6. The binding of [3H]naloxone was temperature-dependent; it increased when the incubation temperatures were elevated from 0 degree C to 37 degrees C. 7. Results obtained for this urodele amphibian are compared with those available for other vertebrate species.

Thermodynamic analysis of the drug-receptor interaction

Thermodynamic analysis of pharmacologic data potentially offers an insight into the molecular events underlying drug-receptor interactions not obtainable by other techniques. Embodied in thermodynamics are the laws governing the interconvertibility of heat and work and, hence, it is a particularly apt framework for the analysis of the transduction of information from ligand to biological tissue during the initiation of a drug effect. Implicit in thermodynamic analysis of pharmacologic data is quantitative measurement of the driving forces involved in the drug-receptor interaction (in place of less precise terms such as "affinity"). In addition, the cautious interpretation of thermodynamic analysis can give clues to the underlying mechanisms of the drug-receptor interaction that is beyond the resolving power of other parameters, such as the dissociation constant. The present review is an attempt to identify representative reports that have overtly analyzed pharmacologic data with thermodynamic analysis, to summarize the findings within and across studies (particularly regarding enthalpy- versus entropy-driven binding of agonists and antagonists), to point out and address some apparent inconsistencies that can arise, and to consider the application of thermodynamic analysis to data obtained using isolated tissue preparations.