Effect of asymmetry of concentration-response curves on the results obtained by the receptorial responsiveness method (RRM): an in silico study

The receptorial responsiveness method (RRM) was proposed to estimate changes in the concentration of an agonist in the microenvironment of its receptor. Usually, this is done by providing the equieffective concentration of another agonist for the same receptor or for a largely overlapping postreceptorial signaling ("test agonist"). The RRM is a special nonlinear regression algorithm to analyze a concentration-response (E/c) curve that represents the simultaneous actions of a single agonist concentration to be estimated and of increasing concentrations of the test agonist. The aim of this study was to explore whether asymmetry of the E/c curve to be analyzed influences the reliability of the RRM. For this purpose, computer simulation was performed by constructing symmetric and asymmetric E/c curves using the operational model of agonism, and then these curves were analyzed with the RRM. To perform the RRM, 2 types of equations were used: one involving the Hill equation, the simplest model of the E/c relationship, and one containing the Richards equation, an advanced model properly handling E/c curve asymmetry. Results of this study indicate that E/c curve asymmetry does not significantly influence the accuracy of the estimates provided by the RRM. Thus, when using the RRM, it is not necessary to replace the Hill equation with the Richards equation to obtain useful estimates. Furthermore, it was found that estimation of a high concentration of a high-efficacy agonist can fail when the RRM is performed with a low-efficacy test agonist in a system characterized by a small operational slope factor.     

Functional consequences of agonist-mediated state transitions in the cholinergic receptor. Studies in cultured muscle cells.

Parameters associated with activation and desensitization of the nicotinic receptor in the BC3H-1 muscle cell line have been compared with the state transitions that result upon combination with agonist. 125I-labeled cobra alpha-toxin is found to bind to an apparent single class of surface nicotinic receptors on the cells in situ with a rate constant of 1.15 x 10(5) M-1 s-1. The competition between cholinergic ligands and alpha-toxin reveals that agonists, but not classical antagonists, will promote a slow conversion to a receptor state where the affinity for agonists is enhanced. Moreover, agonists such as carbamylcholine elicit a permeability increase to 22Na+ ions that slowly decrements at a rate and to an extent closely paralleled by the conversion of the receptor to the high affinity state. Upon removal of the agonist, both the affinity increase and the diminished permeability change are completely reversible and again exhibit similar kinetics for their return to the original state. A comparison of the capacity of full agonists to compete with alpha-toxin binding and elicit a permeability change suggests that in the absence of agonist, receptor predominates in a low affinity activatable state. Binding of agonists to the low affinity state exhibits little if any cooperativity (n = 0.97 to 1.31), while the corresponding permeability change appears more cooperative (n = 1.31 to 1.52). By contrast, when receptors have been previously equilibrated with agonists, occupation of the receptor occurs over a 3- to 5-fold lower concentration range. Binding following equilibration closely correlates with a concomitant decrease in activatable receptor resulting from equivalent exposure to agonist. Furthermore, under equilibrium conditions, the binding of full agonists is typified by a moderate degree of homotropic cooperativity (1.25 to 1.44), enabling the receptor to desensitize over a narrow range of agonist concentration. Simultaneous measurement of occupation and activation parameters has enabled us to compare a state function for desensitization which is generated from binding parameters with the reduction in permeability seen in the desensitization process. A scheme describing the association of agonist with two functionally distinct receptor states is developed to account for the cooperative relationship between agonist binding and desensitization of the receptor.     

A1 Adenosine Receptor-G Protein Coupling in Bovine Brain Membranes: Effects of Guanine Nucleotides, Salt, and Solubilization

The effects of guanine nucleotides, NaCl, and solubilization on the interaction of antagonists and agonists with the A1 adenosine receptor of bovine brain membranes were studied using the high-affinity antagonist radioligand [3H]xanthine amine congener ([3H]XAC). In membranes, guanine nucleotides and NaCl had no effect on [3H]XAC saturation curves. Using agonist (R)-phenylisopropyladenosine (R-PIA) competition curves versus [3H]XAC, it was demonstrated that agonists could differentiate two affinity states having high and low affinity for agonist and that guanine nucleotides shifted the equilibrium to an all-low-affinity state that was indistinguishable from the low-affinity state in the absence of guanine nucleotides. In contrast, NaCl decreased agonist affinity by a distinctly different mechanism characterized by a parallel rightward shifted agonist curve such that R-PIA still recognized two affinity states albeit of lower affinity than in the absence of salt. R-PIA competition curves in the presence of both guanine nucleotides and salt were still shallow but were shifted far to the right, and two very low affinity states were discerned. On solubilization, guanine nucleotides in a reversible, concentration-dependent manner increased antagonist ([3H]XAC) but not agonist (R-N6-[3H]phenylisopropyladenosine) binding. This was consequent to a change in maximal binding capacity. R-PIA competition curves (versus [3H]XAC) in solubilized preparations demonstrated that agonist could still differentiate two agonist specific affinity states which were modulated by guanine nucleotides. In the presence of guanine nucleotides all the receptors were shifted to a uniform low-affinity state. In contrast, NaCl had no effect on agonist affinity as determined by agonist competition curves in a solubilized receptor preparation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Anterior pituitary dopamine receptors. Demonstration of interconvertible high and low affinity states of the D-2 dopamine receptor

The interactions of dopaminergic agonists and antagonists with binding sites in bovine anterior pituitary membranes have been investigated with radioligand-binding techniques and computer-modeling procedures. 3H-labeled agonist binding is stereospecific, reversible, saturable, and of high affinity. The rank order of catecholamines, phenothiazines, and related drugs in competing for 3H-agonist binding is indicative of interactions with a D-2 dopamine receptor. Both agonist/3H-agonist and antagonist/3H-agonist competition curves are monophasic and noncooperative (nH = 1) with computer analysis indicating a single class of binding sites. Specific 3H-agonist binding can be completely inhibited by guanine nucleotides. GppNHp us the most potent nucleotide followed by GTP and GDP which are equipotent. The equilibrium binding capacity for 3H-labeled antagonists is twice that for 3H-agonists. Unlabeled antagonists inhibit 3H-antagonist binding competitively and exhibit antagonist/3H-antagonist competition curves which model best to a state of homogeneous affinity. In contrast, unlabeled agonists inhibit 3H-antagonist binding in a heterogeneous fashion displaying multiphasic (nH less than 1) competition curves which can be resolved into high and low affinity binding sites. In the presence of saturating concentrations of guanine nucleotides, however, the agonist/3H-antagonist curves model best to a single affinity state which is identical with the low affinity state seen in control curves. The binding data can be explained by postulating two states of the D-2 dopamine receptor, inducible by agonists but not antagonists and modulated by guanine nucleotides.     

Low affinity of beta-adrenergic receptors for agonists on intact cells is not due to receptor sequestration

The low affinity of beta-adrenergic receptors for agonists described on intact cells at 37 degrees C has usually been interpreted in terms of reduced accessibility of agonists (which are usually hydrophilic) for sequestered receptors. We challenged this hypothesis by eliminating the plasma membrane barrier with low doses of the detergent digitonin. In human mononuclear leukocytes (MNL) permeabilized with digitonin, sequestered receptors became accessible to hydrophilic ligands such as agonists, but the affinity was still low. Then we investigated the relationship between low affinity agonist binding and sequestration using concanavalin A, which blocks sequestration. Even when sequestration was blocked, the affinity of the beta-adrenergic receptors for agonists was low. We conclude that: (a) low affinity agonist binding is independent of receptor sequestration; (b) the receptors which undergo conformational change are those that are sequestered; (c) the low affinity appears before sequestration occurs. This receptor conformational change could be the first step in agonist-induced desensitization.     

Estimation of the affinity of naloxone at supraspinal and spinal opioid receptors in vivo: studies with receptor selective agonists

The apparent affinity of naloxone at cerebral and spinal sites was estimated using selective mu [D-Ala2, Gly-o15]-enkephalin (DAGO) and delta [D-Pen2, D-Pen5]enkephalin] (DPDPE) opioid agonists in the mouse warm water tail-withdrawal test in vivo; the mu agonist morphine was employed as a reference compound. The approach was to determine the naloxone pA2 using a time-dependent method with both agonist and antagonist given intracerebroventricularly (i.c.v.) or intrathecally (i.th.); naloxone was always given 5 min before the agonist. Complete time-response curves were determined for each agonist at each site in the absence, and in the presence, of a single, fixed i.c.v. or i.th. dose of naloxone. From these i.c.v. or i.th. pairs of time-response curves, pairs of dose-response lines were constructed at various times; these lines showed decreasing displacement with time, indicative of the disappearance of naloxone. The graph of log (dose ratio-1) vs. time was linear with negative slope, in agreement with the time-dependent form of the equation for competitive antagonism. From this plot, the apparent pA2 and naloxone half-life was calculated at each site and against each agonist. The affinity of naloxone was not significantly different when compared between agonists after i.c.v. administration. A small difference was seen between the affinity of i.th. naloxone against DPDPE and DAGO; the i.th. naloxone pA2 against morphine, however, was not different than that for DPDPE and DAGO. The naloxone half-life varied between 6.6 and 16.9 min, values close to those previously reported for this compound. These results suggest that the agonists studied may produce their i.c.v. analgesic effects at the same receptor type or that alternatively, the naloxone pA2 may be fortuitously similar for mu and delta receptors in vivo. Additionally, while the affinity of naloxone appears different for the receptors activated by i.th. DAGO and DPDPE, further work may be necessary before firm conclusions regarding the nature of the spinal analgesic receptor(s) can be drawn.     

Agonist-induced isomerization of the alpha 1-adrenergic receptor: kinetic analysis using broken-cell and solubilized preparations

The affinity of agonists but not antagonists at hepatic membrane alpha 1-adrenergic receptors is temperature dependent; a 100-fold higher affinity is observed at 4 degrees C than at 37 degrees C. The relationship between these two agonist affinity states was investigated by using a strategy that allows the kinetics of this transition to be examined under equilibrium conditions. When competition assays are performed at 37 degrees C for varying intervals and the reaction mixture is then rapidly cooled by freezing, allowed to thaw, and further equilibrated at 4 degrees C, a rapid and progressive decrease (t1/2 of 1-2 min) in agonist affinity occurs, the extent of which is directly related to the incubation time at 37 degrees C. This decrease in agonist affinity is sustained as long as agonist is present but can be reversed by its subsequent removal. In contrast, no change in affinity is seen in identical experiments when antagonists are employed as the competing ligand. High-affinity binding of agonists is also demonstrated in short-term nonequilibrium experiments, indicating that the low-temperature incubations do not induce, but rather stabilize, a receptor conformation of high affinity for agonists. These findings suggest that the predominantly low-affinity binding of agonists to alpha 1-adrenergic receptors demonstrated in equilibrium studies at physiological temperatures may be the result of a ligand-driven decrease in affinity. Since the transition in receptor affinity for agonists occurs not only in broken-cell preparations but also after detergent solubilization of the membrane receptor, it most likely is due to an agonist-induced change in the conformation of the receptor protein per se.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutations of aspartate 103 in the Hm2 receptor and alterations in receptor binding properties of muscarinic agonists

Aspartate 103 (D103) in the third transmembrane domain of the Hm2 receptor was mutated to glutamate (D103E), asparagine (D103N), or alanine (D103A). As measured by [3H]-NMS, no significant binding was observed in D103A, while a 2-fold decrease in ligand affinity was seen in D103E and a 32-fold decrease in affinity was found in the D103N mutant. Examination of reference agonists showed greater loss of affinity in D103N than in D103E with the rank order of change being: L-607,207>carbachol>arecoline>pilocarpine>oxotremorine>McN-A-343. Of the novel 1-azabicyclo[2.2.1]-heptan-3-one oxime agonists examined, arylacetylene oximes showed little alteration in binding in either the D103E or D103N mutants, while the geometric isomers of several bicyclic aryl-ene-yne oximes showed significant changes in affinity, especially in the D103N mutant. Thus, overall size of the agonist and/or spatial orientation of the molecule within the binding pocket contribute to changes measured in binding.     

Ligand-specific state transitions of the membrane-bound acetylcholine receptor

We have developed a simple, direct and time-resolved method to monitor ligand-induced changes in agonist affinity of the membrane-bound acetylcholine receptor. The assay is based on the quenching of fluorescence of NBD-5-acylcholine observed upon binding of this cholinergic agonist to the receptor. Under conditions of partial saturation with the fluorescent agonist, agonists and local anesthetics but not antagonists can induce an increase in affinity of the receptor for NBD-5-acylcholine. The effect is not observed with receptor fully saturated with the fluorescent agonist. The half-life of the observed change in affinity is independent of the nature of the agonist or local anesthetic applied (t1/2 approximately 60 s at 22 degrees C). We conclude that the same state transition of the receptor can be induced by two groups of cholinergic ligands that are assumed to be non-competitive with each other and to have distinctly different modes of action. The time course of the transition is reminiscent of the slow process of desensitization observed in vivo.     

Interactions of novel dopaminergic ligands with D-1 and D-2 dopamine receptors

The interactions of three novel dopaminergic ligands, SKF38393, SKF82526 and SKF83742, with D-1 and D-2 dopamine (DA) receptors have been investigated using radioligand binding techniques and computer modeling procedures. Using the bovine anterior pituitary D-2 DA receptor system, SKF38393 and SKF82526 behave as agonists demonstrating biphasic agonist/3H-antagonist competition curves. For both drugs, the high affinity phase comprised 30% of the total displacement curve. Such findings are atypical as previously tested classical dopamine agonists demonstrated high and low affinity displacement phases in equal proportions. Such behavior exhibited by the SKF agonists may be related to their activity as partial agonists. In contrast, SKF83742 behaves as an antagonist exhibiting homogeneous monophasic competition curves. Similar results are obtained in the rat striatal membrane D-2 DA receptor system. Both SKF38393 and SKF82526 also demonstrate shallow biphasic displacement curves on rat striatal D-1 receptors labeled with 3H-flupentixol whereas SKF83742/3H-flupentixol curves are uniphasic. Of all the ligands, only SKF38393 clearly demonstrates higher affinity for 3H-flupentixol labeled D-1 receptors.     

Dual effects of muscarinic M2 receptors on the synthesis of cyclic AMP in CHO cells: background and model

It has been observed in several laboratories that muscarinic agonists have dual effects on the synthesis of cyclic AMP in cell lines expressing muscarinic M2 or M4 receptors, producing strong inhibition at low agonist concentrations and lesser inhibition or stimulation at high agonist concentrations. Data obtained on CHO cells (known to express adenylyl cyclases VI and VII) are best interpreted on the assumption that the upward phase of the concentration-response curves reflects simultaneous inhibition of adenylyl cyclase VI via the Gi proteins, with which the M2 and M4 receptors communicate with high affinity, and stimulation of adenyly cyclases VI and VII via the Gs proteins, with which the M2 and M4 receptors communicate with low affinity. A simplified model is described which permits one to predict how the shapes of the concentration-response curves will be affected by changes in the concentration of receptors, the affinities of activated receptors for Gi or Gs proteins, and other parameters.     

Interaction of l-Prolyl-l-Leucyl Glycinamide with Dopamine D2 Receptor: Evidence for Modulation of Agonist Affinity States in Bovine Striatal Membranes

The role of the hypothalamic tripeptide L-prolyl-L-leucyl-glycinamide (PLG) in modulating the agonist binding to bovine striatal dopamine D2 receptor was investigated using a selective high-affinity agonist, n-propylnorapomorphine (NPA). PLG caused an enhancement in [3H]NPA binding in striatal membranes in a dose-dependent manner, the maximum effect being observed at 10(-7)-10(-6) M concentration of the tripeptide. The Scatchard analysis of [3H]NPA binding to membranes preincubated with 10(-6) M PLG revealed a significant increase in the affinity of the agonist binding sites. In contrast, there was no effect of PLG on the binding pattern of the antagonist [3H]spiroperidol. The antagonist versus agonist competition curves analyzed for agonist high- and low-affinity states of the receptor displayed an increase in the population and affinity of the high-affinity form of the receptor with PLG treatment. The low-affinity sites concomitantly decreased with relatively small change in the affinity for the agonists. Almost similar results were obtained when either NPA or apomorphine was used in the competition experiments. A partial antagonistic effect of PLG on 5'-guanylylimidodiphosphate [Gpp(NH)p]-induced inhibition of high-affinity agonist binding was also observed, as the ratio of high- to low-affinity forms of the receptor was significantly higher in the PLG-treated membranes compared to the controls. Direct [3H]NPA binding experiments demonstrated that PLG attenuated the Gpp(NH)p-induced inhibition of agonist binding by increasing the EC50 of the nucleotide (concentration that inhibits 50% of the specific binding). No effect of PLG on high-affinity [3H]NPA binding, however, could be observed when the striatal membranes were preincubated with Gpp(NH)p.(ABSTRACT TRUNCATED AT 250 WORDS)     

组胺H3受体激活剂高通量筛选细胞模型的研究

摘 要 目的 建立基于报告基因的组胺H3受体（H3R）激活剂的高通量筛选模型,用此模型对收集到的中草药化合物组分进行筛选,以发现新的组胺H3R激活剂。 方法 将H3R基因质粒（H3R/pCDNA3.1-hygro）与报告基因质粒（3XCRE-LUC）按3：1的比例共转染入HEK293细胞,建立了稳定的H3R配体的报告基因筛选细胞株。激活剂与细胞表面H3R结合后,激活相应的信号通路,调节Forskolin刺激后的报告基因的表达,通过测定荧光素酶报告基因表达水平的变化,评估激活剂影响H3受体的生物活性。 结果 通过对筛选条件,如激活剂孵育时间、Forskolin终浓度、化合物溶剂的选择、溶剂DMSO终浓度等的优化,建立了可靠的筛选方法,并对多种中草药萃取物进行了筛选,找到了两种对H3R有活性的中药组分。结论 建立的细胞模型可以有效的应用于以组胺H3受体为靶点的高通量药物筛选。     

Agonist-induced changes in beta-adrenergic receptors on intact cells

Competition by beta-adrenergic agonists and antagonists for 125I-pindolol binding sites on intact cells (1321N1 human astrocytoma and C62B rat glioma) was measured using short time binding assays as previously described (Toews, M. L., Harden, T. K., and Perkins, J. P. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 3553-3557). Preincubation of cells with agonists converted about half of the cellular beta-adrenergic receptors from a form exhibiting high affinity for the agonists isoproterenol and epinephrine and the antagonist sotalol to a form exhibiting much lower apparent affinity for these ligands in short time assays. Exposure to agonists did not alter the affinity of receptors for the antagonist metoprolol. This change in the ligand binding properties of the receptor was rapid (t1/2 = 1-2 min following a lag of about 0.5 min), reversible (t1/2 = 6-8 min), and dependent on the agonist concentration present during the preincubation (K0.5 = 15 nM for isoproterenol). Both isoproterenol and sotalol attained equilibrium with the high affinity receptors very rapidly but equilibrated only slowly with those receptors exhibiting low apparent affinity in short time assays. These results are interpreted in terms of a model which postulates that both the low apparent affinity in short time assays and the subsequent slow equilibration of hydrophilic ligands with these receptors result from agonist-induced internalization of a fraction of cell surface beta-adrenergic receptors. The relationship of this change in receptor binding properties to other aspects of agonist-induced desensitization of the beta-adrenergic receptor-coupled adenylate cyclase system is discussed.     

Guanyl nucleotide and divalent cation regulation of cortical S2 serotonin receptors

Computer-assisted quantitative analysis of radioligand binding to rat cortical S2 serotonin receptors indicates the existence of two affinity states of the same receptor population. Monophasic antagonist competition curves for [3H]ketanserin-labelled sites suggest a uniform population of receptors with one affinity state for antagonists. Biphasic competition curves of agonists suggest that agonists discriminate high- and low-agonist-affinity forms of the S2 receptors. The affinities of agonists for the high- and low-affinity states, and the apparent percentages of high agonist-affinity forms varies with different agonists. The guanine nucleotides GTP and guanyl-5'-imido-diphosphate [Gpp(NH)p], as well as divalent cations, modulate the proportion of the sites with high affinity for agonists as evidenced by their ability to shift the agonist competition curves for [3H]ketanserin-labelled S2 receptors. GTP and Gpp(NH)p effects appear to be agonist-specific, as they do not affect antagonist competition for [3H]ketanserin-labelled S2 receptors, or [3H]ketanserin binding to S2 receptors. ATP and ADP have little or no effect on the binding properties of S2 serotonin receptors, whereas GDP is less potent than GTP. The presence of these specific nucleotide effects are the first evidence suggesting involvement of a guanine nucleotide-binding protein in the mechanism of agonist interaction with the S2 serotonin receptor. In general, the binding properties of [3H]ketanserin-labelled S2 serotonin receptors strongly resemble those of adenylate-cyclase coupled receptors such as the beta-adrenergic, the alpha 2-receptor, and the D-2 dopamine receptor. This may indicate the S2 serotonin receptor is coupled to adenylate cyclase activity, through a GTP binding protein.     

Agonist Interactions with Beta-Adrenergic Receptors Following Chronic Administration of Desipramine or the Atypical Antidepressants,Iprindole and Mianserin

Abstract

Desipramine (DMI), decreased the maximum number of beta-adrenergic receptors by approximately 10, 20, 30, and 20% in groups of rats treated i.p. with 5 mg/kg for 14 days or 10 mg/kg for 7, 14, or 21 days, respectively. In studies of agonist competition for beta-adrenergic receptors labelled with [¹²⁵I]-CYP, chronic DMI administration caused a selective decrease in those receptors normally found in the high affinity conformation in proportion to the dose of DMI administered. No change was observed in either the number of receptors in the agonist low affinity conformation or in the affinity of any drug for the high or low affinity conformations of the receptors. Therefore, chronic DMI caused a selective decrease in the beta-adrenergic receptors linked to adenylate cyclase but did not appear to change other properties of the receptors that would be manifested as a change in their ability to interact with adrenergic agonists. Neither iprindole (15 mg/kg i.p., 14 days) nor mianserin (10 mg/kg i.p., 14 days) decreased the number of receptors, the proportions of agonist high or low affinity receptors, or the affinity of competitor drugs for these receptors, suggesting a different mechanism for the reported loss of adenylate cyclase activity following these drugs than the down-regulation of receptors observed with chronic DMI treatment.     

Coupling of G Proteins to Reconstituted Monomers and Tetramers of the M2 Muscarinic Receptor

G protein-coupled receptors can be reconstituted as monomers in nanodiscs and as tetramers in liposomes. When reconstituted with G proteins, both forms enable an allosteric interaction between agonists and guanylyl nucleotides. Both forms, therefore, are candidates for the complex that controls signaling at the level of the receptor. To identify the biologically relevant form, reconstituted monomers and tetramers of the purified M₂ muscarinic receptor were compared with muscarinic receptors in sarcolemmal membranes for the effect of guanosine 5′-[β,γ-imido]triphosphate (GMP-PNP) on the inhibition of N-[³H]methylscopolamine by the agonist oxotremorine-M. With monomers, a stepwise increase in the concentration of GMP-PNP effected a lateral, rightward shift in the semilogarithmic binding profile (i.e. a progressive decrease in the apparent affinity of oxotremorine-M). With tetramers and receptors in sarcolemmal membranes, GMP-PNP effected a vertical, upward shift (i.e. an apparent redistribution of sites from a state of high affinity to one of low affinity with no change in affinity per se). The data were analyzed in terms of a mechanistic scheme based on a ligand-regulated equilibrium between uncoupled and G protein-coupled receptors (the “ternary complex model”). The model predicts a rightward shift in the presence of GMP-PNP and could not account for the effects at tetramers in vesicles or receptors in sarcolemmal membranes. Monomers present a special case of the model in which agonists and guanylyl nucleotides interact within a complex that is both constitutive and stable. The results favor oligomers of the M₂ receptor over monomers as the biologically relevant state for coupling to G proteins.     

Time course of isolated rat fundus response to muscarinic agonists: a measure of intrinsic efficacy.

The establishment of a dose-response relationship and its quantification is the usual procedure for analysing drug action on an isolated organ. However, the time course of the effect seems to be an inherent characteristic of the agonist which produces it. In our study, we have analyzed the time-response curves of four cholinergic agonists (acetylcholine, methacholine, carbachol and bethanechol) which produce tonic contractions of the isolated rat gastric fundus. The order of affinity of agonists to muscarinic receptors on the rat fundus were carbachol > bethanechol > methacholine > acetylcholine (K(A) values: 46 +/- 12, 84 +/- 21, 380 +/- 110 and 730 +/- 120 nM, respectively). The effective concentrations which produced 60% of the maximal response (EC60) were used for establishing the time-response curves. The time-response curves were also recorded after partial alkylation of muscarinic receptors with phenoxybenzamine, after exposure of the isolated rat fundus to physostigmine and after addition of supramaximal concentrations of the agonists. The experimental time-response curve for acetylcholine was on the extreme left, followed by curves for methacholine, bethanechol and carbachol, respectively. Phenoxybenzamine and supramaximal doses of the agonists did not change the order of response development in time, but supramaximal doses shifted all curves to the left and phenoxybenzamine shifted all time-response curves to the right. Only physostigmine shifted the time-response curve for methacholine to the right. The results of our study suggest that the response rate of the isolated rat gastric fundus to cholinergic agonists depends on the intrinsic activity of these agents, but not on their affinity for muscarinic receptors.     

Correlation of agonist-induced phosphorylation of chick heart muscarinic receptors with receptor desensitization

We have determined whether the process of agonist-mediated phosphorylation of the muscarinic receptor correlates with the process of muscarinic receptor desensitization in chick cardiac tissue. Exposure of ventricular slices to the agonist carbachol under conditions previously shown to lead to large increases in muscarinic receptor phosphorylation (Kwatra, M. M., and Hosey, M. M. (1986) J. Biol. Chem. 261, 12429-12432) resulted in decreased affinity of the muscarinic receptor for agonists. The agonist oxotremorine mimicked and the antagonist atropine prevented the effects of carbachol on receptor phosphorylation and agonist affinity. The time courses and concentration dependences for agonists to induce phosphorylation of the muscarinic receptor and decreases in agonist affinity were similar. Treatment of chick atria with acetylcholine under conditions which led to receptor phosphorylation resulted in decreased sensitivity of these preparations to the negative inotropic effect of carbachol. Taken together, the results support the concept that phosphorylation of cardiac muscarinic receptors may be related to the process of receptor desensitization. The mechanism by which agonists induce receptor phosphorylation was also investigated. The phosphorylated amino acids formed in response to agonists were serine and threonine. The protein kinase C activator phorbol myristate acetate had no effect on receptor phosphorylation or agonist affinity, nor did it prevent the effects of carbachol on either of these parameters. Receptor phosphorylation also was unaffected by the calmodulin antagonists W-7 and W-13, by elevation of cyclic nucleotides, and by agonists which activate other cardiac receptor systems. The results suggest that the phosphorylation of cardiac muscarinic receptors requires agonist occupancy of the receptor and/or may involve the participation of a selective protein kinase.     

Modification of peptide interaction with MHC creates TCR partial agonists

We report the creation of TCR partial agonists by the novel approach of manipulating the interaction between immunogenic peptide and MHC. Amino acids at MHC anchor positions of the I-E(k)-restricted hemoglobin (64-76) and moth cytochrome c (88-103) peptides were exchanged with MHC anchor residues from the low affinity class II invariant chain peptide (CLIP), resulting in antigenic peptides with altered affinity for MHC class II. Several low affinity peptides were identified as TCR partial agonists, as defined by the ability to stimulate cytolytic function but not proliferation. For example, a peptide containing methionine substitutions at positions one and nine of the I-E(k) binding motif acted as a partial agonist for two hemoglobin-reactive T cell clones (PL.17 and 3.L2). The identical MHC anchor substitutions in moth cytochrome c (88-103) also created a partial agonist for a mCC-reactive T cell (A.E7). Thus, peptides containing MHC anchor modifications mediated similar T cell responses regardless of TCR fine specificity or antigen reactivity. This data contrasts with the unique specificity among individual clones demonstrated using traditional altered peptide ligands containing substitutions at TCR contact residues. In conclusion, we demonstrate that altering the MHC anchor residues of the immunogenic peptide can be a powerful method to create TCR partial agonists.