Using microphysiometry to study the pharmacology of exogenously expressed m1 and m3 muscarinic receptors

Enzyme electrodes to monitor glucose consumption of single cardiac myocytes in sub-nanoliter volumes

Monitoring the metabolic activity of cells in automated culture systems is one of the key features of micro-total-analysis-systems. We have developed a microfluidic device that allows us to trap single cardiac myocytes (SCMs) in sub-nanoliter volumes and incorporate amperometric glucose-sensing electrodes with working areas of 0.002 mm(2) to measure the glucose consumption of SCM. The miniaturized planar glucose electrodes were fabricated by spin coating platinum electrodes on glass substrates with a glutaraldehyde/enzyme solution and a protective Nafion membrane. The glucose electrodes demonstrate a high enzymatic activity characterized by an apparent Michaelis-Menten constant of 7.52+/-0.18 mM and a sensitivity of approximately 33.8 and approximately 13.2 mA/Mcm(2) at glucose concentration from 0-6 to 6-20 mM in Tyrode's solution, respectively. The response time of the glucose electrodes was between 5 and 15s, and the sensitivity of the electrodes did not degrade over a period of 8 weeks. A replica molded polydimethylsiloxane microfluidic device with a sub-nanoliter sensing volume was sealed to the glass substrate and aligned with the glucose microelectrodes. SCM can be trapped in the sensing volume above the glucose electrodes to measure the glucose consumption over time. The average glucose consumption of SCM was 0.211+/-0.097 mM/min (n=7) in Tyrode's solution with 5 mM of glucose.

Ligand characterization using microphysiometry

This unit describes the use of a Cytosensor microphysiometer for functional characterization of an agonist and antagonist to a G protein-coupled receptor, the muscarinic M1 receptor. Concentration-response profiles are used to calculate values for the EC50 of the response of cells to the agonist and the pA2 value for the antagonist. Support protocols describe optimization of two aspects of this procedure: the duration of ligand exposure at a given concentration and the length of recovery time between the administration of two different concentrations of ligand to minimize the impact of desensitization. The Cytosensor microphysiometer allows the measurement of receptor activation in both adherent cells, such as the M1WT3 cells used here or in suspension cultures.

Designing human m1 muscarinic receptor-targeted hydrophobic eigenmode matched peptides as functional modulators

A new proprietary de novo peptide design technique generated ten 15-residue peptides targeting and containing the leading nontransmembrane hydrophobic autocorrelation wavelengths, "modes", of the human m(1) muscarinic cholinergic receptor, m(1)AChR. These modes were also shared by the m(4)AChR subtype (but not the m(2), m(3), or m(5) subtypes) and the three-finger snake toxins that pseudoirreversibly bind m(1)AChR. The linear decomposition of the hydrophobically transformed m(1)AChR amino acid sequence yielded ordered eigenvectors of orthogonal hydrophobic variational patterns. The weighted sum of two eigenvectors formed the peptide design template. Amino acids were iteratively assigned to template positions randomly, within hydrophobic groups. One peptide demonstrated significant functional indirect agonist activity, and five produced significant positive allosteric modulation of atropine-reversible, direct-agonist-induced cellular activation in stably m(1)AChR-transfected Chinese hamster ovary cells, reflected in integrated extracellular acidification responses. The peptide positive allosteric ligands produced left-shifts and peptide concentration-response augmentation in integrated extracellular acidification response asymptotic sigmoidal functions and concentration-response behavior in Hill number indices of positive cooperativity. Peptide mode specificity was suggested by negative crossover experiments with human m(2)ACh and D(2) dopamine receptors. Morlet wavelet transformation of the leading eigenvector-derived, m(1)AChR eigenfunctions locates seven hydrophobic transmembrane segments and suggests possible extracellular loop locations for the peptide-receptor mode-matched, modulatory hydrophobic aggregation sites.

Spatially resolved monitoring of cellular metabolic activity with a semiconductor-based biosensor

Metabolic activity of cultured cells can be monitored by measuring changes in the pH of the surrounding medium caused by metabolic products such as protons, carbon dioxide or lactic acid. Although many systems designed for this purpose have been reported, almost all of them are based on bulk measurements, where the average metabolic activity of all cells in contact with the device is recorded. Here, we report on a novel biosensor, based on a modified light-addressable potentiometric sensor (LAPS) device, which enables the metabolic activity of cultured cells to be measured with spatial resolution. This is demonstrated here by detecting the differential sensitivity to a cholinergic receptor agonist of two different co-cultured cellular populations. By making simultaneous measurements of the metabolic activity of different cell types seeded on different segments of one sensor, this device not only provides a rapid means of assessing cellular specificity of pharmaceutical compounds but also has the potential of being used to non-invasively monitor humoral as well as synaptic communication between different cell populations in co-culture. The temporal and spatial resolution of the device were investigated and are discussed.

Real-time analysis of the activities of GnRH and GnRH analogs in alphaT3-1 cells by the Cytosensor microphysiometer

Gonadotropin-releasing hormone (GnRH), acting via the GnRH receptor, elicited rapid extracellular acidification responses in mouse gonadotrope-derived alphaT3-1 cells as measured by the Cytosensor microphysiometer, which indirectly monitors cellular metabolic rates. GnRH increased the extracellular acidification rate of the cells in a dose-dependent manner (EC(50) = 1.81 +/- 0.24 nM). The GnRH-stimulated acidification rate could be attenuated by protein kinase C (PKC) down-regulation, extracellular Ca2+ depletion, and the voltage-sensitive Ca2+ channel (VSCC) blocker nifedipine, indicating that the acidification response is activated by both Ca2+ and PKC-mediated pathways. Upon continuous exposure to 100 nM GnRH or periodic stimulation by 10 nM GnRH at 40 min intervals, homologous desensitization was more pronounced in the absence of extracellular Ca2+, suggesting that desensitization of GnRH activity may be mediated via depletion of intracellular Ca2+ stores. We have also compared the potency of eight GnRH analogs on alphaT3-1 cells. No acidification response was detected for GnRH free acid, consistent with the idea that the C-terminal amide is a critical structural determinant for GnRH activity. Replacement of Gly-NH(2) at the C-terminus by N-ethylamide dramatically reduced the EC(50) value, suggesting that substitution of the Gly-NH(2) moiety by N-ethylamide increases the potency of GnRH analogs. Substitution of Gly at position 6 by D-Trp significantly reduced the EC(50) value, whereas D-Lys at the same position slightly increased the EC(50) value, implying that either an aromatic amino acid or a non-basic amino acid at position 6 may be essential for potent GnRH agonists. In summary, our results demonstrate that the Cytosensor microphysiometer can be used to evaluate the actions of GnRH and GnRH analogs in alphaT3-1 cells in a real-time and noninvasive manner. This silicon-based microphysiometric system should provide new information on the structure-function studies of GnRH and is an invaluable tool for the screening of new GnRH agonists and antagonists in the future.

Functional characterization of rat submaxillary gland muscarinic receptors using microphysiometry

1. Muscarinic cholinoceptors (MChR) in freshly dispersed rat salivary gland (RSG) cells were characterized using microphysiometry to measure changes in acidification rates. Several non-selective and selective muscarinic antagonists were used to elucidate the nature of the subtypes mediating the response to carbachol. 2. The effects of carbachol (pEC(50) = 5.74 +/- 0.02 s.e.mean; n = 53) were highly reproducible and most antagonists acted in a surmountable, reversible fashion. The following antagonist rank order, with apparent affinity constants in parentheses, was noted: 4-DAMP (8.9)= atropine (8.9) > tolterodine (8.5) > oxybutynin (7.9) > S-secoverine (7.2) > pirenzepine (6.9) > himbacine (6.8) > AQ-RA 741 (6.6) > methoctramine (5.9). 3. These studies validate the use of primary isolated RSG cells in microphysiometry for pharmacological analysis. These data are consistent with, and extend, previous studies using alternative functional methods, which reported a lack of differential receptor pharmacology between bladder and salivary gland tissue. 4. The antagonist affinity profile significantly correlated with the profile at human recombinant muscarinic M(3) and M(5) receptors. Given a lack of antagonists that discriminate between M(3) and M(5), definitive conclusion of which subtype(s) is present within RSG cells cannot be determined.

The metabolic evidence of synergistic effect between ohmefentanyl and [D-Pen2, D-Pen5] enkephalin on differentiated SH-SY5Y cells in humans

Interactions between selective opioid agonists acting at mu- and delta-opioid receptors were evaluated by co-administering a low-effective dose of the selective mu-opioid receptor agonist ohmefentanyl (OMF) with sequentially increasing doses of the selective delta-opioid receptor agonist [D-Pen(2), D-Pen(5)] enkephalin (DPDPE). Microphysiometer was used to measure the extracellular acidification rate (ECAR) of living cells in real-time, which reflected the functional activity after agonist-receptor binding. The synergy (i.e. a more than additive effect) was observed with combinations of these two opioid agonists on differentiated SH-SY5Y cells functionally expressing both mu- and delta-opioid receptors. The demonstration of the synergy suggests that the agonists of the subtypes of opioid receptors can interact at cellular level.

Functional and ultrastructural cell pathology induced by fuel oil in cultured dolphin renal cells

Investigations were undertaken to elucidate in a marine mammal renal cell culture system the toxicity and some of the mechanisms of cytopathology in a standardized preparation following exposure to No. 1 fuel oil. Cell survivability of a cultured SP1K renal cell line from the Atlantic spotted dolphin Stenella plagiodon was reduced in a dose-dependent manner after a 12-h exposure to fuel oil. Early morphologic changes reflecting cytotoxicity, as revealed by transmission electron microscopy, included enlarged rough endoplasmic reticula, cytoplasmic vacuolization, and degenerative cytoplasmic inclusions, but mitochondria remained resistant. Assessment of extracellular proton loss by microphysiometry of cultured cells revealed fuel oil-induced enhancement of proton loss that was dependent upon both protein kinase C and renal epithelial Na(+)/H(+) counter-transport functioning, as the specific inhibitors H-7 and amiloride reduced this stimulatory petroleum effect. Cell cycle progression and apoptosis (programmed cell death) were studied in dolphin renal cells exposed to fuel oil for 12, 24, and 48 hours. The toxicant increased the percentage of cells in GO/GI phase and decreased the percentage of cells in S phase starting after 24 hours. The number of cells undergoing early apoptosis was also increased after 24 hours.

Equilibrium and kinetic measurements of muscarinic receptor antagonism on living cells using bead injection spectroscopy

Bead injection spectroscopy (BIS) techniques are introduced for automated measurement of pharmacological antagonism by functional assay. Chinese hamster ovary cells that express the rat type 1 muscarinic receptor are cultured on microbeads and used as a renewable biological target for muscarinic receptor antagonist ligands. A flow injection instrument is used to reproducibly sample and capture the cells in a jet ring chamber. The effect of the antagonist pirenzepine on the carbachol-induced intracellular calcium response of the cells is measured with a fluorescence microscope photometry system. The BIS functional assay is used to quantify both equilibrium and kinetic pharmacological values for pirenzepine. In addition, two muscarinic receptor antagonists (pirenzepine and atropine) are assayed to compare their relative efficacy at diminishing the calcium response. Due to the precision of the automated fluid/bead handling protocols, and reproducibility of the measured calcium response, the quantification of useful pharmacological information from living cells by BIS techniques is demonstrated.

Ca2+ mobilization and activation of extracellular acidification by carbachol in acutely dispersed cells from guinea pig detrusor: Fura 2 fluorometry and microphysiometry using the cytosensor

The study aim was to develop a simple in vitro model for pharmacophysiological investigation of urinary bladder smooth muscles. Smooth muscle cells from guinea pig detrusor were dissociated, and the suspended cells were stimulated with carbachol (CCh), an acetylcholine receptor agonist. Cytosolic Ca2+ levels were determined using Fura 2 fluorescence and extracellular acidification rates were monitored by the Cytosensor microphysiometer. CCh dose-dependently increased cytosolic Ca2+ levels and extracellular acidification rates, with EC50 values of approximately 1 microM. Both the acetylcholine muscarinic receptor antagonist atropine and the M3 muscarinic receptor-preferring antagonist 4-diphenylacetoxy-N-methylpiperidine (4-DAMP) inhibited the effects of CCh, three orders of magnitude more potently than the selective M2 muscarinic receptor antagonist, methoctramine. These data indicate the dominant role of M3 receptors in guinea-pig bladder but fail to show clear evidence of any functional role for M2 receptors. Since this finding agrees with a number of other studies using in vivo and in vitro models (1), cell suspensions such as these may prove to be simple tools for the pharmacological study of urinary bladder smooth muscle tissue.

Automation of functional assays by flow injection fluorescence microscopy

Bead-injection spectroscopy is a novel technique that uses immobilized eukaryotic cells on microbeads as a renewable biosensor for fluorescence microscopy. The use of a flow injection instrument allows fast functional assays that generate full kinetic characterization of a drug. Because the cell population is automatically replaced for each assay, variability is minimized, thus allowing greater accuracy.

Role of N-linked glycosylation on the function and expression of the human secretin receptor

Secretin is a 27-amino acid long peptide hormone that regulates pancreatic water, bicarbonate, enzymes, and potassium ion secretion. The human secretin receptor (hSR) is a glycoprotein consisting of 440 amino acids, of which there are 5 putative N-linked glycosylation sites at positions Asn72, Asn100, Asn106, Asn128 (N-terminal ectodomain), and Asn291 (second exoloop). Through functional analysis of the hSR-transfected cells cultured in the presence of various glycosylation inhibitors, it was found that tunicamycin and castanospermine were able to significantly reduce the secretin-stimulated cAMP response. On the other hand, the effects of other inhibitors, swainsonine and deoxymannojirimycin, were much lower, suggesting that the high mannose-type carbohydrate side-chain is essential to the expression of a fully functional hSR. The role of individual N-linked glycosylation sites was studied by mutation analysis (Asn to Leu or Ser to Ala) coupled to measurements of cAMP accumulation and extracellular acidification rate. The ED50 values of the wild-type receptor in these two assay systems were 0.25 and 0.11 nM, respectively, and mutation at position 100, 106, or 291 did not affect either the ED50 values or the maximal responses in the two assays. However, the Asn72Leu and Ser74Ala mutations reduced the maximal responses and increased the ED50 values in both assays, suggesting that this site is a true glycosylation signal. This hypothesis was further supported by competitive binding studies, the same mutants were found to be defective in binding with [125I]secretin. To evaluate whether the change in receptor function of the mutants is caused by the change in the process of presenting the receptor to the cell surface, the mutants and the wild-type receptor were tagged with a c-Myc epitope at the C-termini. Using an anti-c-Myc monoclonal antibody and confocal microscopy, all of the mutant receptors were found to be expressed and delivered to the plasma membrane.

Identification of distinct signalling pathways for somatostatin receptors SSTR1 and SSTR2 as revealed by microphysiometry

Somatostatin receptors (SSTRs) are known to mediate diverse cellular responses. Most target cell express more than one SSTR isoform, making it difficult to define the signalling pathway used by individual receptor subtypes. Thus, we have expressed SSTR1 or SSTR2 in rat pituitary F4C1 cells which lack endogenous SSTRs. Using a silicon-based biosensor system, the Cytosensor microphysiometer, which measures the extracellular acidification rate (ECAR) in real time, we have studied the responses to SS mediated by either SSTR1 or SSTR2. In control F4C1 cells, SS had no effect on the basal ECAR. In transfected cells expressing only SSTR1, SS caused a unique decrease in ECAR in a concentration-dependent manner. Receptor-mediated decreases in ECAR have not been reported previously. In F4C1 cells expressing only SSTR2, SS induced a bidirectional ECAR response, a rapid increase followed by a decrease below basal. Two SS analogues, MK678 and CH275, induced characteristic ECAR responses with the expected receptor selectivities for SSTR1 or SSTR2. Pretreatment of F4C1 cells with pertussis toxin abolished the decreases in ECAR mediated by both SSTR1 and SSTR2, but only partially reduced the increase in ECAR mediated by SSTR2. The decrease in ECAR did not depend on a decrease in intracellular cAMP. The ECAR responses to SS were modestly attenuated by methylisobutylamiloride (MIA), an inhibitor of the ubiquitous Na(+)-H+ exchanger NHE1. Removal of extracellular Na+ greatly inhibited the ECAR responses to SS, demonstrating a role for both amiloride-sensitive and -insensitive Na(+)-dependent acid transport mechanisms in SS-induced extracellular acidification. In conclusion, we have identified and characterized different signalling pathways for SSTR1 and SSTR2 in pituitary cells as measured by microphysiometry.

Functional comparison of muscarinic partial agonists at muscarinic receptor subtypes hM1, hM2, hM3, hM4 and hM5 using microphysiometry

1. This study describes the pharmacological comparison of the muscarinic partial agonists sabcomeline, xanomeline and milameline at human cloned muscarinic receptor subtypes (hM1-5). 2. Radioligand binding studies at the hM1-5 muscarinic receptor subtypes were compared with functional studies using microphysiometry using carbachol as the standard full agonist. 3. In binding assays none of the compounds studied displayed preferential affinity for the M1,3,4 or M5 subtypes although carbachol was less potent at hM1 than hM3,4,5. 4. In functional studies, all of the compounds studied displayed similar levels of efficacy across the muscarinic receptors with the exception of M3, where there was a large apparent receptor reserve and the compounds behaved essentially as full agonists. 5. Sabcomeline was the most potent agonist in functional studies but also showed the lowest efficacy. In terms of potency, xanomeline showed some selectivity for M1 over M2 receptors and milameline showed some selectivity for M2 over M1 receptors. 6. These results show the value of microphysiometry in being able to compare receptor pharmacology across subtypes irrespective of the signal transduction pathway. 7. None of the partial agonists showed functional selectivity for M1 receptors, or indeed any muscarinic receptor, in the present study.

Flow injection microscopy for the study of intracellular calcium mobilization by muscarinic agonists

The study of cellular response to chemical agonists is essential in understanding the complex functions mediated by cell surface receptors. Flow injection microscopy has been used with the CHO-M1-WT3 cell line and the fluorescent Ca2+ indicator Fura-2-AM to monitor mobilization of internal Ca2+. Repeated stimulation of cells mounted in an inverted radial flow chamber allows the direct comparison of relative intracellular Ca2+ mobilization with respect to agonist dose. The process of determining dose-response relationships is simplified since an entire dose-response curve can be constructed from a distinct set of cells. Use of flow injection lends precision to the application and removal of agonists while allowing cellular activity to be monitored throughout the stimulation and recovery processes. In this work, dose-response curves have been constructed for the muscarinic agonists carbachol, acetylcholine, and pilocarpine resulting in EC50 values of 1.7 microM, 56 nM, and 6.8 microM, respectively.

A flow injection renewable surface technique for cell-based drug discovery functional assays

A novel flow injection-renewable surface (FI-RS) technique is introduced for the execution of automated pharmacology-based assays on living cells. Cells are attached to microcarrier beads, which serve as the disposable and renewable surface with which the assay is performed. The feasibility of this FI-RS technique is demonstrated by performing a functional assay using Chinese hamster ovary cells transfected with the rat muscarinic receptor (M1). The intracellular calcium elevation resulting from the agonist-receptor interaction is measured via a calcium-sensitive fluorescent probe (fura-2) and a fluorescence microscope photometry system. The FI apparatus allows reproducible and precise control of the concentration gradient of chosen muscarinic receptor agonists (carbachol, acetylcholine, pilocarpine) delivered to cells attached to microcarrier beads. The RS methodology eliminates problems associated with diminishing biological response vis-à-vis traditional functional assays that are performed repetitively on the same group of cells. Using this technique, reproducible responses are measured and pharmacologic parameters quantified that compare favorably to literature values. In addition, the use of the FI-RS functional assay as an analytical method for discrimination of agonists based on kinetic parameters is proposed.

Thermal imaging of receptor-activated heat production in single cells

Changes in enthalpy (i.e., heat content) occur during the diverse intracellular chemical and biophysical interactions that take place in the life cycle of biological cells. Such changes have previously been measured for cell suspensions or cell-free biochemical extracts by using microcalorimetry, thermocouples, or pyroelectric films, all of which afford minimal spatial or temporal resolution. Here we present a novel thermal imaging method that combines both diffraction-limited spatial (approximately 300 nm) and sampling-rate-limited time resolution, using the temperature-dependent phosphorescence intensity of the rare earth chelate Eu-TTA (europium (III) thenoyltrifluoro-acetonate). With this thermosensitive dye, we imaged intracellular heat waves evoked in Chinese hamster ovary cells after activation of the metabotropic m1-muscarinic receptor. Fast application of acetylcholine onto the cells evoked a biphasic heat wave that was blocked by atropine, and after a brief delay was followed by a calcium wave. Atropine applied by itself produced a monophasic heat wave in the cells, suggesting that its interactions with the receptor activate some intracellular metabolic pathways. The thermal imaging technique introduced here should provide new insights into cellular functions by resolving the location, kinetics, and quantity of intracellular heat production.

Activation of neurotensin receptors and purinoceptors in human colonic adenocarcinoma cells detected with the microphysiometer

Activation of endogenous neurotensin (NT) receptors and P2-purinoceptors expressed by human colonic adenocarcinoma HT-29 cells increased extracellular acidification rates that were detected in the microphysiometer. NT (pGlu-Leu-Tyr-Glu-Asn-Lys-Pro-Arg-Arg-Pro-Tyr-Ile-Leu), NT[8-13] (Arg-Arg-Pro-Tyr-Ile-Leu), NT[9-13] (Arg-Pro-Tyr-Ile-Leu), and NT1 (N alpha methyl-Arg-Lys-Pro-Trp-Tle-Leu [Tle = tert-leucine]) were full agonists, whereas XL 775 (N-[N-[2-[3-[[6-amino-1-oxo-2-[[(phenylmethoxy)carbonyl]-amino]hex yl]amino]phenyl]-3-(4-hydroxyphenyl)-1-oxo-2-propenyl]-L-isoleucyl]-L-le ucine) was a partial agonist for activating NT receptors expressed by HT-29 cells. Desensitization induced by NT was rapid and monophasic with 85% of the initial response lost by a 30-s exposure. Once initiated, the rate and extent of desensitization were similar for different concentrations of a given agonist, for agonists of different potencies, and for agonists of different efficacies, which suggests that desensitization may be independent of receptor occupancy or agonist efficacy. Resensitization was a much slower process, requiring 60 min before the full agonist response to NT was recovered. ATP, via P2-purinoceptors, also activated cellular acidification rates in a concentration-dependent manner. ATP induced a biphasic desensitization of purinoceptors with a loss of ca. 50% of the initial stimulation detectable between 30 and 90 s of exposure to the agonist. Desensitization of NT receptors did not influence the activation of P2-purinoceptors by ATP, suggesting there was no heterologous desensitization between the two types of receptors. Superfusion with NT receptor agonists for 15 min at concentrations that did not elicit changes in extracellular acidification rates blocked, in a concentration-dependent manner, the agonist response induced by 100 nM NT. This may reflect sequestration of the receptor. These results suggest that the high agonist affinity state of NT receptors may modulate receptor sequestration, whereas activation of the low agonist affinity state may be linked to cellular metabolism. Comparison of our results with published data found differences as well as similarities of NT responses among three lines of HT-29 cells.

Signal transduction mediated by the truncated trkB receptor isoforms, trkB.T1 and trkB.T2

The trkB family of transmembrane proteins serves as receptors for BDNF and NT-4/5. The family is composed of a tyrosine kinase-containing isoform as well as several alternatively spliced "truncated receptors" with identical extracellular ligand-binding domains but very small intracellular domains. The two best-characterized truncated trkB receptors, designated as trkB.T1 and trkB.T2, contain intracellular domains of only 23 and 21 amino acids, respectively. Although it is known that the tyrosine kinase isoform (trkB.FL) is capable of initiating BDNF and NT-4/5-induced signal transduction, the functional role or roles of the truncated receptors remain enigmatic. At the same time, the potential importance of the truncated receptors in the development, maintenance, and regeneration of the nervous system has been highlighted by recent developmental and injury paradigm investigations. Here we have used trkB cDNA transfected cell lines to demonstrate that both trkB.T1 and trkB.T2 are capable of mediating BDNF-induced signal transduction. More specifically, BDNF activation of either trkB.T1 or trkB.T2 increases the rate of acidic metabolite release from the cell, a common physiological consequence of many signaling pathways. Further, these trkB.T1- and trkB. T2-mediated changes occur with kinetics distinct from changes mediated by trkB.FL, suggesting the participation of at least some unique rate-limiting component or components. Mutational analysis demonstrates that the isoform-specific sequences within the intracellular domains of each receptor are essential for signaling capability. Finally, inhibitor studies suggest that kinases are likely to be involved in the trkB.T1 and trkB.T2 signaling pathways.

Dual effects of endothelin-1 on extracellular acidification by A7r5 smooth muscle cells

The effect of endothelin-1 on metabolic activity of A7r5 rat aortic smooth muscle cells was studied. Endothelin-1 (pEC(50) 7.5) elicited an increase in the rate of extracellular medium acidification of the A7r5 cells. The ETA receptor antagonist BQ-123 blocked the endothelin-1 effect completely (pA(2) 7.6). Ca2+ channel blockers affected the endothelin-1 induced response in different ways: diltiazem and nifedipine partially blocked the endothelin-1 induced response, whereas verapamil did not influence this endothelin-1 induced effect. However, upon removal of verapamil an endothelin-1 dependent rise in extracellular acidification occurred, apparently reflecting the lifting of the verapamil blockade of an endothelin-1 induced process. Thus, this study shows that the complex integrated cellular responses upon ET-1 receptor activation are reflected in metabolic activity.