Endothelin ET(B) receptors show different binding profiles in intact cells and cell membrane preparations

Clozapine, atypical antipsychotics, and the benefits of fast-off D2 dopamine receptor antagonism

Drug-receptor interactions are traditionally quantified in terms of affinity and efficacy, but there is increasing awareness that the drug-on-receptor residence time also affects clinical performance. While most interest has hitherto been focused on slow-dissociating drugs, D(2) dopamine receptor antagonists show less extrapyramidal side effects but still have excellent antipsychotic activity when they dissociate swiftly. Fast dissociation of clozapine, the prototype of the "atypical antipsychotics", has been evidenced by distinct radioligand binding approaches both on cell membranes and intact cells. The surmountable nature of clozapine in functional assays with fast-emerging responses like calcium transients is confirmatory. Potential advantages and pitfalls of the hitherto used techniques are discussed, and recommendations are given to obtain more precise dissociation rates for such drugs. Surmountable antagonism is necessary to allow sufficient D(2) receptor stimulation by endogenous dopamine in the striatum. Simulations are presented to find out whether this can be achieved during sub-second bursts in dopamine concentration or rather during much slower, activity-related increases thereof. While the antagonist's dissociation rate is important to distinguish between both mechanisms, this becomes much less so when contemplating time intervals between successive drug intakes, i.e., when pharmacokinetic considerations prevail. Attention is also drawn to the divergent residence times of hydrophobic antagonists like haloperidol when comparing radioligand binding data on cell membranes with those on intact cells and clinical data.

Long-lasting target binding and rebinding as mechanisms to prolong in vivo drug action

An increasing number of examples in the literature suggest that the in vivo duration of drug action not only depends on macroscopic pharmacokinetic properties like plasma half-life and the time needed to equilibrate between the plasma and the effect compartments, but is also influenced by long-lasting target binding and rebinding. The present review combines information from different research areas and simulations to explore the nature of these mechanisms and the conditions in which they are most prevalent. Simulations reveal that these latter phenomena become especially influential when there is no longer sufficient free drug around to maintain high levels of receptor occupancy. There is not always a direct link between slow dissociation and long-lasting in vivo target protection, as the rate of free drug elimination from the effect compartment is also a key influencing factor. Local phenomena that hinder the diffusion of free drug molecules away from their target may allow them to consecutively bind to the same target and/or targets nearby (denoted as 'rebinding') even when their concentration in the bulk phase has already dropped to insignificant levels. The micro-anatomic properties of many effect compartments are likely to intensify this phenomenon. By mimicking the complexity of tissues, intact cells offer the opportunity to investigate both mechanisms under the same, physiologically relevant conditions.

Rebinding: or why drugs may act longer in vivo than expected from their in vitro target residence time

IMPORTANCE OF THE FIELD

It is well established that the in vivo duration of drug action not only depends on macroscopic pharmacokinetic properties like its plasma half-life, but also on the residence time of the drug-target complexes. However, drug 'rebinding' (i.e., the consecutive binding of dissociated drug molecules to the original target and/or targets nearby) can be influential in vivo as well.

AREAS COVERED IN THIS REVIEW

Information about rebinding is available since the 1980s but it is dispersed in the life sciences literature. This review compiles this information. In this respect, neurochemists and biopohysicians advance the same equations to describe drug rebinding.

WHAT THE READER WILL GAIN

The rebinding mechanism is explained according to the prevailing viewpoint in different life science disciplines. There is a general consensus that high target densities, high association rates and local phenomena that hinder the diffusion of free drug molecules away from their target all promote rebinding.

TAKE HOME MESSAGE

Simulations presented here for the first time suggest that rebinding may increase the duration and even the constancy of the drug's clinical action. Intact cell radioligand dissociation and related ex vivo experiments offer useful indications about a drug's aptitude to experience target rebinding.

Binding of NIR-conPK and NIR-6T to astrocytomas and microglial cells: evidence for a protein related to TSPO

PK 11195 and DAA1106 bind with high-affinity to the translocator protein (TSPO, formerly known as the peripheral benzodiazepine receptor). TSPO expression in glial cells increases in response to cytokines and pathological stimuli. Accordingly, [¹¹C]-PK 11195 and [¹¹C]-DAA1106 are recognized molecular imaging (MI) agents capable of monitoring changes in TSPO expression occurring in vivo and in response to various neuropathologies.

Here we tested the pharmacological characteristics and TSPO-monitoring potential of two novel MI agents: NIR-conPK and NIR-6T. NIR-conPK is an analogue of PK 11195 conjugated to the near-infrared (NIR) emitting fluorophore: IRDye 800CW. NIR-6T is a DAA1106 analogue also conjugated to IRDye 800CW.

We found that NIR-6T competed for [³H]-PK 11195 binding in astrocytoma cell homogenates with nanomolar affinity, but did not exhibit specific binding in intact astrocytoma cells in culture, indicating that NIR-6T is unlikely to constitute a useful MI agent for monitoring TSPO expression in intact cells. Conversely, we found that NIR-conPK did not compete for [³H]-PK 11195 binding in astrocytoma cell homogenate, but exhibited specific binding in intact astrocytoma cells in culture with nanomolar affinity, suggesting that NIR-conPK binds to a protein distinct, but related to, TSPO. Accordingly, treating intact astrocytoma cells and microglia in culture with cytokines led to significant changes in the amount of NIR-conPK specific binding without corresponding change in TSPO expression. Remarkably, the cytokine-induced changes in the protein targeted by NIR-conPK in intact microglia were selective, since IFN-γ (but not TNFα and TGFβ) increased the amount of NIR-conPK specific binding in these cells.

Together these results suggest that NIR-conPK binds to a protein that is related to TSPO, and expressed by astrocytomas and microglia. Our results also suggest that the expression of this protein is increased by specific cytokines, and thus allows for the monitoring of a particular subtype of microglia activation.

Antagonist-D2S-dopamine receptor interactions in intact recombinant Chinese hamster ovary cells [corrected]

D(2)-type dopamine receptors are major recognition sites for antipsychotic drugs. There are two splice variants: D(2S) and D(2L) with an additional 29 amino acid sequence in the third intracellular loop. Only little comparative information is hitherto available about their pharmacological properties and none of these studies dealt with intact cell systems. This prompted us to investigate the binding properties of [(3)H]-raclopride, a hydrophilic benzamide, and [(3)H]-spiperone, a highly hydrophobic butyrophenone, to intact CHO cells expressing recombinant human D(2L)-receptors. Presently, we have repeated and extended this experimental approach to the human D(2S)-receptors in the same cell system. Except for a slower dissociation of [(3)H]-spiperone from D(2S), the binding properties of these and other antagonists were not significantly different for both isoforms (P > 0.05). The very slow dissociation of the atypical antipsychotic clozapine was surprising in light of its low affinity. Two experiments pointed out the existence of non-competitive interactions between raclopride and spiperone for D(2S) as well as D(2L) (A. Packeu, J. P. De Backer & G. Vauquelin, in preparation). Alongside the different physicochemical properties of these ligands, this finding fits with a model wherein the hydrophilic raclopride approaches the D(2L)-receptor from the aqueous phase, while the hydrophobic spiperone approaches the receptor by lateral diffusion between the membrane lipids. These different modes of approach could imply the existence of topologically distinct ligand binding sites at D(2)-receptors.

Ligands, their receptors and ... plasma membranes

Ligand-receptor interactions are customarily described by equations that apply to solutes. Yet, most receptors are present in cell membranes so that sufficiently lipophilic ligands could reach the receptor by a two-dimensional approach within the membrane. As summarized in this review, this may affect the ligand-receptor interaction in many ways. Biophysicians calculated that, compared to a three-dimensional approach from the liquid phase, such approach could alter the time the ligands need to find a receptor. Biochemists found that ligand incorporation in lipid bilayers modifies their conformation. This, along with the depth at which the ligands reside in the bilayer, will affect the probability of successful receptor interaction. Novel mechanisms were also introduced, including "exosite" binding and ligand translocation between the receptor's alpha-helical transmembrane domains. Pharmacologists focused attention at ligand concentrations in membrane, their adsorption and release rates and the effects thereof on ligand potency and residence time at the receptor.

Non-competitive interaction between raclopride and spiperone on human D-receptors in intact Chinese hamster ovary cells

We recently investigated the binding properties of the antagonists [(3)H]-raclopride and [(3)H]-spiperone to intact Chinese hamster ovary cells expressing recombinant human D(2long)-dopamine receptors (CHO-D(2L) cells). Compared with saturation binding with [(3)H]-raclopride, raclopride reduced [(3)H]-spiperone binding with to low potency in competition binding experiments. The present findings illustrate the ability of spiperone to inhibit [(3)H]-raclopride binding non-competitively. While raclopride only decreases the apparent K(D) of [(3)H]-raclopride in saturation binding experiments, spiperone only decreases the number of sites to which [(3)H]-raclopride binds with high affinity. Also, while the IC(50) of raclopride depends on the concentration of [(3)H]-raclopride in competition experiments, this is not the case for spiperone. Kinetic studies reveal that the binding of raclopride at its high affinity sites does not affect the association of subsequently added [(3)H]-spiperone nor the rebinding of freshly dissociated [(3)H]-spiperone to the same or surrounding receptors. Yet, spiperone does not affect the dissociation rate of [(3)H]-raclopride and raclopride does not affect the (genuine) dissociation rate of [(3)H]-spiperone. The easiest way to interpret the present findings in molecular terms is to assume that D(2L)-receptors or their dimeric complexes possess two distinct binding sites: one with high affinity/accessibility for [(3)H]-raclopride and the other one with high affinity/accessibility for [(3)H]-spiperone. The ability of bound spiperone to inhibit high affinity raclopride binding while the reverse is not the case suggests for the occurrence of non-reciprocal allosteric interactions. These new findings could point at the occurrence of allosteric interactions between different classes of D(2)-receptor antagonists.

Unravelling the complex dissociation of [(3)H]-rimonabant from plated CB(1) cannabinoid receptor-expressing cells

The dissociation profile of the antagonist [(3)H]-rimonabant from recombinant CB(1) cannabinoid receptors expressed in plated HEK293 cells followed a complex pattern when measured in medium only. After a rapid decline, the specific binding levelled off at about 20% below the initial value. To unravel the responsible mechanism(s), we examined the relative contribution of binding to cells and walls of the culture wells respectively. Washout was also performed in the presence of an excess of unlabelled ligand and/or bovine serum albumin (BSA). The findings suggest that dissociated [(3)H]-rimonabant molecules not only undergo rebinding to the same or neighbouring receptors but also partition in the cell membranes and fix to the walls. As these non-receptor associations still occur in presence of unlabelled ligand, they can be erroneously regarded to represent 'specific binding'. While the unlabelled ligand was most effective in preventing receptor rebinding, BSA was most effective in preventing non-receptor associations. To measure receptor-dissociation only, washout is best performed in presence of unlabelled ligand and BSA or any other protein that can pick-up free radioligand molecules. Yet, washout in medium only could hint at mechanisms that affect the in vivo residence time of the drug in question.

Sartan-AT1 receptor interactions: in vitro evidence for insurmountable antagonism and inverse agonism

Sartans are non-peptide AT(1) receptor antagonists used to treat hypertension and related pathologies. Their effects on the G protein-dependent responses of angiotensin II (Ang II) were the same in vascular tissues and in isolated cell systems. All are competitive but, when pre-incubated, they act surmountably (only rightward shift of the Ang II concentration-response curve) or insurmountably (also decreasing the maximal response). Insurmountable behaviour reflects the formation of tight sartan-receptor complexes; it is often partial due to the co-existence of tight and loose complexes. Their ratio positively correlates with the dissociation half-life of the tight complexes and depends on the sartan: i.e. candesartan>olmesartan>telmisartan approximately equal EXP3174>valsartan>irbesartan>>losartan. When AT(1) receptors display sufficient basal activity (in case of receptor over-expression, mutation and, especially, tissue stretching) sartans may also act as inverse agonists. This rather affects long-term, G protein-independent hypertrophic responses leading to cardiovascular remodelling.

Antagonist-radioligand binding to D2L-receptors in intact cells

D(2)-dopamine receptors mediate most of the physiological actions of dopamine and are important recognition sites for antipsychotic drugs. Earlier binding studies were predominantly done with broken cell preparations with the tritiated D(2)-receptor antagonists [(3)H]-raclopride, a hydrophilic benzamide, and [(3)H]-spiperone, a highly hydrophobic butyrophenone. Here we compared [(3)H]-raclopride and [(3)H]-spiperone binding properties in intact Chinese Hamster Ovary cells stably expressing recombinant human D(2L)-receptors. Specific binding of both radioligands occurred to a comparable number of sites. In contrast to the rapid dissociation of [(3)H]-raclopride in both medium only and in the presence of an excess of unlabelled ligand [(3)H]-spiperone dissociation was only observed in the latter condition, and it was still slower than in broken cell preparations. However, this could not explain the pronounced difference in the potency of some unlabelled ligands to compete with both radioligands. To integrate these new findings, a model is proposed in which raclopride approaches the receptor from the aqueous phase, while spiperone approaches the receptor by lateral diffusion within the membrane.

Functional analysis of cell-free-produced human endothelin B receptor reveals transmembrane segment 1 as an essential area for ET-1 binding and homodimer formation

The functional and structural characterization of G-protein-coupled receptors (GPCRs) still suffers from tremendous difficulties during sample preparation. Cell-free expression has recently emerged as a promising alternative approach for the synthesis of polytopic integral membrane proteins and, in particular, for the production of G-protein-coupled receptors. We have now analyzed the quality and functional folding of cell-free produced human endothelin type B receptor samples as an example of the rhodopsin-type family of G-protein-coupled receptors in correlation with different cell-free expression modes. Human endothelin B receptor was cell-free produced as a precipitate and subsequently solubilized in detergent, or was directly synthesized in micelles of various supplied mild detergents. Purified cell-free-produced human endothelin B receptor samples were evaluated by single-particle analysis and by ligand-binding assays. The soluble human endothelin B receptor produced is predominantly present as dimeric complexes without detectable aggregation, and the quality of the sample is very similar to that of the related rhodopsin isolated from natural sources. The binding of human endothelin B receptor to its natural peptide ligand endothelin-1 is demonstrated by coelution, pull-down assays, and surface plasmon resonance assays. Systematic functional analysis of truncated human endothelin B receptor derivatives confined two key receptor functions to the membrane-localized part of human endothelin B receptor. A 39 amino acid fragment spanning residues 93-131 and including the proposed transmembrane segment 1 was identified as a central area involved in endothelin-1 binding as well as in human endothelin B receptor homo-oligomer formation. Our approach represents an efficient expression technique for G-protein-coupled receptors such as human endothelin B receptor, and might provide a valuable tool for fast structural and functional characterizations.

Salicylic acid alters endothelin-1 binding in intact adult rat ventricular myocytes

Endothelin receptors ETAR and ETBR form tight receptor–ligand complexes that complicate our understanding of the physiological, pharmacological, and biochemical properties of these receptors. Although radioligand–binding studies have demonstrated the binding of endothelin-1 (ET-1) to ETAR to be essentially irreversible, ETAR internalize in a ligand-dependent manner, release ET-1, and then recycle to the cell surface. Salicylic acid (SA) reduces ET-1 binding (IC50= 10 mmol/L) to recombinant ETAR in isolated membranes by promoting dissociation of [125I]ET-1. In the present study, SA (5 mmol SA/L) did not alter [125I]ET-1 binding to intact adult rat ventricular myocytes. The lack of effect was not due to internalization of receptor–ligand complexes. However, 100 mmol SA/L significantly reduced [125I]ET-1 binding to both intact myocytes and isolated membranes. SA induced the phosphorylation p42/44 extracellular signal-regulated kinase (ERK) mitogen-activated protein (MAP) kinase and an unidentified 40-kDa protein on the activating threonine-glutamic acid-tyrosine (T-E-Y) motif. ERK phosphorylation was reduced by a MAP kinase kinase (MEK) inhibitor, PD98059. Phosphorylation of p40 was reduced by the p38 MAP kinase inhibitor SB203580, but not PD98059. However, inhibition of ERK or p38 MAP kinases did not alter the ability of 100 mmol SA/L to induce dissociation of [125I]ET-1. These results suggest that, in the ventricular myocyte, salicylic acid alters the kinetics of ET-1 binding. The results also suggest an allosteric binding site may be present that modulates the dissociation of ET-1 receptor–ligand complexes in response to an as-of-yet unidentified mediator.Key words: cell communication, endothelin, endothelin receptor, inotropic agents, signal transduction, heart, ventricular myocyte.

Effect of saponin and filipin on antagonist binding to AT 1 receptors in intact cells

In the present study, [ 3H ]-candesartan binding experiments were performed on intact Chinese Hamster Ovary cells transfected with the human AT1 receptor (CHO-AT1 cells). Cells were pre-treated with 0.01mg/ml saponin or filipin. Both pre-treatments resulted in an increased dissociation rate and decreased affinity of the insurmountable non-peptide antagonist [3H ]-candesartan. A similar decrease in affinity was observed for the peptide antagonist Sar1-Ile8 angiotensin II and for other non-peptide antagonists, irrespectively of their degree of insurmountability. A similar discrepancy in [ 3H ]-candesartan binding was earlier observed when comparing intact CHO-AT1 cells and membrane preparations thereof. This similarity is further highlighted by the observations that saponin or filipin no longer affect [ 3H ]-candesartan binding to CHO-AT1 cell membranes and that both agents permeabilise the CHO-AT1 cells. This suggests that the intracellular composition and/or organisation of living cells play an active role with regard to antagonist-AT1 receptor interactions.

Distinct binding properties of the AT(1) receptor antagonist [(3)H]candesartan to intact cells and membrane preparations

[(3)H]-2-Ethoxy-1-[(2'-(1H-tetrazol-5-yl)biphenyl-4-yl)methyl]-1H-benzimidazoline-7-carboxylic acid ([(3)H]candesartan), a non-peptide angiotensin II type 1 receptor (AT(1) receptor) antagonist bound with high affinity and specificity to intact adherent human AT(1) receptor transfected Chinese hamster ovary cells. The binding characteristics were preserved when cells were suspended, but the dissociation was 3-4-fold faster and the affinity 2-fold lower, while examining [(3)H]candesartan binding to cell membranes. These data suggested the role of the intracellular organisation of living CHO-hAT(1) cells in antagonist-AT(1) receptor interactions. Yet, a specific role of microtubule or actin filaments of the cytoskeleton, receptor phosphorylation by Protein Kinase C, membrane polarity, cytoplasmic components like ATP and the need of an intact cell membrane could be excluded. The potential effect of protease degradation or receptor oxidation during the membrane preparation was also unlikely. The dissociation rate and the equilibrium dissociation constant of [(3)H]candesartan increased with the temperature for both intact cells and membranes. Thermodynamic studies suggested that the bonds between candesartan and the hAT(1) receptor may be of different nature in intact CHO-hAT(1) cells and membranes thereof. Whereas the binding was almost completely enthalpy-driven on intact cells, there was a mixed contribution of both enthalpy and entropy on membranes.

Pharmacological characterization of endothelin receptor subtypes in the guinea-pig prostate gland

Experiments have been conducted to investigate the actions of endothelins on the guinea-pig prostate gland. Saturation experiments with [125I]-endothelin-1 (2-800 pM) in guinea-pig prostatic homogenates indicated the presence of high affinity binding sites with an equilibrium dissociation constant (KD) of 230+/-50 pM, a maximum number of binding sites (Bmax) of 52+/-16 fmol mg(-1) protein or 269+/-61 fmol g(-1) tissue and a Hill coefficient (nH) of 1.01+/-0.03 (n = 3). Competition experiments revealed that binding of [125I]-endothelin-1 (20 pM) was inhibited with the following order of potency: endothelin-1 >>BQ-788 (N-cis-2,6-dimethylpiperidinocarbonyl-L-gamma-methyl-Leu-D-Trp[1-+ ++CO2CH3-D-Nle-ONa])> BQ-123 (cyclo-D-Asp-L-Pro-D-Val-Leu-D-Trp) > or = sarafotoxin S6c. At concentrations with negligible influence on smooth muscle tone, endothelin-1, endothelin-2 and sarafotoxin S6b (1 nM-0.1 microM) produced concentration-dependent potentiation of the contractions evoked by electrical field stimulation with trains of 20 pulses at 10 Hz every 50 s, 0.5 ms pulse width and a dial setting of 60 V. In contrast, the endothelin ET(B) receptor-preferring agonist endothelin-3 (1 nM- 1 microM) was much less potent, and the endothelin ET(B) receptor-selective agonists sarafotoxin S6c and BQ-3020 (Ac-[Ala11,15]-endothelin-1 (6-21)), up to 1 microM, were without effect. The endothelin ET(A) receptor antagonist BQ-123 (1 microM) markedly inhibited the potentiation induced by endothelin-1, endothelin-2 and sarafotoxin S6b while the endothelin ET(B) receptor antagonist BQ-788 (1 microM) was less effective. While our binding data indicates the presence of ET(A) and ET(B) binding sites in the guinea-pig prostate, the endothelin-induced facilitation of neurotransmission to the prostatic smooth muscle is mediated largely via activation of endothelin receptors of the ET(A) subtype.

Downregulation of endothelin B receptor in human melanoma cell lines parallel to differentiation genes

Normal human melanocytes have been shown to respond to the signal peptide endothelin by increased proliferation and melanin formation. Contradictory findings, however, have been reported about which of the two endothelin receptors (EDNRA or EDNRB) is expressed in normal melanocytes and melanoma cells. Moreover it was not clear whether malignant cells differ from their normal precursors in this respect. Screening a melanocyte cDNA library for genes downregulated in melanomas identified clones specific for EDNRB. Northern blots proved that the corresponding mRNA is generally expressed in cultures of human cutaneous melanocytes and congenital melanocytic nevus cells. In 16 of 17 melanoma cell lines, however, the expression of EDNRB mRNA was strongly downregulated. EDNRA was only weakly expressed and detectable by northern blotting in 12 of 17 cultures of benign melanocytic cells and four of 17 melanoma cell lines. Nested reverse transcriptase-polymerase chain reaction proved several melanoma cell lines to be completely negative for EDNRA expression. Gene deletion as the cause of missing endothelin receptor expression was ruled out by genomic Southern blots. Receptor binding assays confirmed RNA data revealing 1.6 x 105 endothelin-1 binding sites per cell for a melanocyte culture and between 8.7 x 104 and 400 sites per cell for melanoma cell lines. Expression of pigmentation genes coding for tyrosinase, TRP-1 and TRP-2 correlated positively with that of EDNRB but negatively with EDNRA expression. EDNRB but not EDNRA expression is therefore typical for melanocytic cells, and downregulation of EDNRB seems to be an important characteristic of melanoma cells possibly related to malignancy or apoptosis.