Short Periods of Hypoxia Upregulate Sphingosine Kinase 1 and Increase Vasodilation of Arteries to Sphingosine 1-Phosphate (S1P) via S1P3.

Sphingosine kinase [(SK), isoforms SK1 and SK2] catalyzes the formation of the bioactive lipid, sphingosine 1-phosphate (S1P). This can be exported from cells and bind to S1P receptors to modulate vascular function. We investigated the effect of short-term hypoxia on SK1 expression and the response of arteries to S1P. SK1 expression in rat aortic and coronary artery endothelial cells was studied using immunofluorescence and confocal microscopy. Responses of rat aortic rings were studied using wire myography and reversible hypoxia induced by bubbling myography chambers with 95% N2:5% CO2 Inhibitors were added 30 minutes before induction of hypoxia. S1P induced endothelium-dependent vasodilation via activation of S1P3 receptors and generation of nitric oxide. Hypoxia significantly increased relaxation to S1P and this was attenuated by (2R)-1-[[(4-[[3-methyl-5-[(phenylsulfonyl)methyl] phenoxy]methyl]phenyl]methyl]-2-pyrrolidinemethanol [(PF-543), SK1 inhibitor] but not (R)-FTY720 methyl ether [(ROMe), SK2 inhibitor]. Hypoxia also increased vessel contractility to the thromboxane mimetic, 9,11-dideoxy-11α,9α-epoxymethanoprostaglandin F2α, which was further increased by PF-543 and ROMe. Hypoxia upregulated SK1 expression in aortic and coronary artery endothelial cells and this was blocked by PF-543 and 2-(p-hydroxyanilino)-4-(p-chlorophenyl)thiazole [(SKi), SK1/2 inhibitor]. The effects of PF-543 and SKi were associated with increased proteasomal/lysosomal degradation of SK1. A short period of hypoxia increases the expression of SK1, which may generate S1P to oppose vessel contraction. Under hypoxic conditions, upregulation of SK1 is likely to lead to increased export of S1P from the cell and vasodilation via activation of endothelial S1P3 receptors. These data have significance for perfusion of tissue during episodes of ischemia.

A comparison of animated versus static images in an instructional multimedia presentation.

Sophisticated three-dimensional animation and video compositing software enables the creation of complex multimedia instructional movies. However, if the design of such presentations does not take account of cognitive load and multimedia theories, then their effectiveness as learning aids will be compromised. We investigated the use of animated images versus still images by creating two versions of a 4-min multimedia presentation on vascular neuroeffector transmission. One version comprised narration and animations, whereas the other animation comprised narration and still images. Fifty-four undergraduate students from level 3 pharmacology and physiology undergraduate degrees participated. Half of the students watched the full animation, and the other half watched the stills only. Students watched the presentation once and then answered a short essay question. Answers were coded and marked blind. The "animation" group scored 3.7 (SE: 0.4; out of 11), whereas the "stills" group scored 3.2 (SE: 0.5). The difference was not statistically significant. Further analysis of bonus marks, awarded for appropriate terminology use, detected a significant difference in one class (pharmacology) who scored 0.6 (SE: 0.2) versus 0.1 (SE: 0.1) for the animation versus stills group, respectively (P = 0.04). However, when combined with the physiology group, the significance disappeared. Feedback from students was extremely positive and identified four main themes of interest. In conclusion, while increasing student satisfaction, we do not find strong evidence in favor of animated images over still images in this particular format. We also discuss the study design and offer suggestions for further investigations of this type.

Previously unsuspected widespread cellular and tissue distribution of ß-adrenoceptors and its relevance to drug action.

The discovery of ß-adrenoceptors in previously unsuspected cell types is contributing to the rethinking of new drug targets. Recent developments in ß-adrenoceptor pharmacology might have excited and surprised James Black, given his interest in developing drugs based on the selective manipulation of receptors to alter physiological responses. ß-adrenoceptors continue to generate surprises at molecular and pharmacological levels that often require knowledge of receptor location to interpret. In this review, we emphasize the use of fluorescent ligands as the most selective means of demonstrating receptor localization. Fluorescent ligand binding in live tissues can provide quantitative pharmacological data, under carefully controlled conditions, relevant to other signalling parameters. Consideration of the role of ß-adrenoceptors in many cell types (previously ignored) is needed to understand the actions of drugs at ß-adrenoceptors throughout the body, particularly in the lung epithelium, vascular endothelium, immune cells and other 'structural' and 'restorative' cell types.

Fluorescent ligand binding reveals heterogeneous distribution of adrenoceptors and 'cannabinoid-like' receptors in small arteries.

BACKGROUND AND PURPOSE: Pharmacological analysis of synergism or functional antagonism between different receptors commonly assumes that interacting receptors are located in the same cells. We have now investigated the distribution of alpha-adrenoceptors, beta-adrenoceptors and cannabinoid-like (GPR55) receptors in the mouse arteries. EXPERIMENTAL APPROACH: Fluorescence intensity from vascular tissue incubated with fluorescent ligands (alpha(1)-adrenoceptor ligand, BODIPY-FL-prazosin, QAPB; beta-adrenoceptor ligand, TMR-CGP12177; fluorescent angiotensin II; a novel diarylpyrazole cannabinoid ligand (Tocrifluor 1117, T1117) was measured with confocal microscopy. Small mesenteric and tail arteries of wild-type and alpha(1B/D)-adrenoceptor-KO mice were used. KEY RESULTS: T1117, a fluorescent form of the cannabinoid CB(1) receptor antagonist AM251, was a ligand for GPR55, with low affinity for CB(1) receptors. In mesenteric arterial smooth muscle cells, alpha(1A)-adrenoceptors were predominantly located in different cells from those with beta-adrenoceptors, angiotensin receptors or cannabinoid-like (GPR55) receptors. Cells with beta-adrenoceptors predominated at arterial branches. Endothelial cells expressed beta-adrenoceptors, alpha-adrenoceptors and cannabinoid-like receptors. Only endothelial alpha-adrenoceptors appeared in clusters. Adventitia was a rich source of G protein-coupled receptors (GPCRs), particularly fibroblasts and nerve tracts, where Schwann cells bound alpha-adrenoceptor, beta-adrenoceptor and CB-receptor ligands, with a mix of separate receptor locations and co-localization. CONCLUSIONS AND IMPLICATIONS: Within each cell type, each GPCR had a distinctive heterogeneous distribution with limited co-localization, providing a guide to the possibilities for functional synergism, and suggesting a new paradigm for synergism in which interactions may be either between cells or involve converging intracellular signalling processes.

Endothelium dependent relaxation in rabbit genital resistance arteries is predominantly mediated by endothelial-derived hyperpolarizing factor in females and nitric oxide in males.

PURPOSE: In nongenital arteries a sex difference has been postulated in the dominant endothelium-derived relaxant factor(s), eg nitric oxide, prostacyclin or endothelial-derived hyperpolarizing factor. Knowledge of endothelium-derived relaxant factor mechanisms in genital tissues could influence the development of novel treatments for sexual dysfunction. We compared nitric oxide and endothelial-derived hyperpolarizing factor contributions to acetylcholine induced relaxation in the genital arteries of the 2 sexes. MATERIALS AND METHODS: Male dorsal and cavernous penile arteries, and female extravaginal and intravaginal arteries from New Zealand White rabbits were studied. Acetylcholine concentration-vasodilator response curves were constructed in the presence of the nitric oxide synthase inhibitor Nomega-nitro-L-arginine methyl ester, K(+) channel blockers (apamin and charybdotoxin) or a combination. Indomethacin was present throughout to exclude prostacyclins. RESULTS: Extravaginal artery relaxation was predominantly endothelial-derived hyperpolarizing factor induced. Apamin plus charybdotoxin decreased maximal relaxations from a mean +/- SEM of 77% +/- 4% to 23% +/- 3% in 6 preparations (p <0.01). However, nitric oxide and endothelial-derived hyperpolarizing factor contributed to overall function. Dorsal artery relaxation was largely nitric oxide induced. Nomega-nitro-L-arginine methyl ester decreased maximal relaxations from 90% +/- 3% to 41% +/- 9% (p <0.001) with no endothelial-derived hyperpolarizing factor involvement (p >0.05). In cavernous and intravaginal arteries nitric oxide and endothelial-derived hyperpolarizing factor contributed to acetylcholine induced relaxation, while nitric oxide predominated. Blocking nitric oxide synthase or K(+) channels indicated that myogenic tone and constitutive activity of endothelium-derived relaxant factors were present. Vasodilator nerve mediated responses were influenced by each with the former more effective. CONCLUSIONS: Vaginal inflow arteries showed a dominance of endothelial-derived hyperpolarizing factor, contrasting with nitric oxide in penile arteries. Penile arteries followed the trend that endothelial-derived hyperpolarizing factor involvement increased with decreasing vessel caliber, while the reverse was demonstrated in female arteries.

Alpha(1A)-adrenoceptors mediate contractions to phenylephrine in rabbit penile arteries.

BACKGROUND AND PURPOSE: Maintained penile erection depends on the absence of alpha-adrenoceptor (alpha-AR) activation and so can be facilitated by alpha-blockers. This study seeks the alpha(1)-AR subtypes involved in order to inform the pro-erectile consequences of subtype selective blockade. EXPERIMENTAL APPROACH: Wire myography was used with dorsal (nutritional supply) and cavernous (erectile inflow) penile arteries; standard alpha-AR-selective agonists and antagonists were employed to classify responses. KEY RESULTS: In both penile arteries noradrenaline (NA) and phenylephrine (PE, alpha(1)-AR agonist) caused concentration-dependent contractions. Sensitivity to NA was increased by NA uptake blockers, cocaine (3 microM) and corticosterone (30 microM). PE responses were antagonised by phentolamine (non-selective alpha-AR: dorsal pK(B) 8.00, cavernous 8.33), prazosin (non-subtype-selective alpha(1)-AR: dorsal 8.60, cavernous 8.41) and RS100329 (alpha(1A)-AR selective: dorsal 9.03, cavernous 8.80) but not by BMY7378 (alpha(1D)-AR selective: no effect at 1-100 nM) or Rec15/2615 (alpha(1B)-AR selective: no effect at 1-100 nM). Schild analysis was straightforward in cavernous artery, indicating that PE activates only alpha(1A)-AR. In dorsal artery Schild slopes were low, though alpha(1A)-AR was still indicated. Analysis using UK 14,304 and rauwolscine indicated an alpha(2)-AR component in dorsal artery that may account for low slopes to alpha(1)-AR antagonists. CONCLUSIONS AND IMPLICATIONS: Penile arteries have a predominant, functional alpha(1A)-AR population with little evidence of other alpha(1)-AR subtypes. Dorsal arteries (nutritional supply) also have alpha(2)-ARs. Thus, alpha-AR blockers with affinity for alpha(1A)-AR or alpha(2)-AR would potentially have pro-erectile properties; the combination of these perhaps being most effective. This should inform the design of drugs to assist/avoid penile erection.

Spatial averaging in the beam of a piston transducer.

This paper presents a theoretical analysis of the spatially averaged free-field responses of phase-sensitive and phase-insensitive receivers centered in the beam of a harmonically excited piston transmitter. The responses of unfocused circular plane piston receivers are analyzed, and both unfocused and spherically focused piston transmitters are considered. A set of closed-form expressions figures prominently in the analysis. The expressions are based on the Lommel diffraction formulation which is, in turn, based on the Fresnel approximation. Although approximate, the expressions allow for quick and easy estimation of phase-sensitive or phase-insensitive unfocused piston receiver responses. It is shown that the spatial averaging effects associated with phase-sensitive and phase-insensitive receivers are virtually identical when gamma < or = 0.1, where gamma = b/a is the ratio of receiver radius b to transmitter radius a. In addition, numerical results obtained from the closed-form expressions are compared with previously reported results. The comparisons indicate that the approximate results are valid from the m = 3 maxima forward under the assumption of linear propagation when ka > 58, where k is the circular wave number. Finally, it is pointed out that the closed-form expressions may prove useful in the estimation of the potential for bioeffects associated with diagnostic ultrasound.

Hypotension, autonomic failure, and cardiac hypertrophy in transgenic mice overexpressing the alpha 1B-adrenergic receptor.

alpha(1)-Adrenergic receptors (alpha(1A), alpha(1B), and alpha(1D)) are regulators of systemic arterial blood pressure and blood flow. Whereas vasoconstrictory action of the alpha(1A) and alpha(1D) subtypes is thought to be mainly responsible for this activity, the role of the alpha(1B)-adrenergic receptor (alpha(1B)AR) in this process is controversial. We have generated transgenic mice that overexpress either wild type or constitutively active alpha(1B)ARs. Transgenic expression was under the control of the isogenic promoter, thus assuring appropriate developmental and tissue-specific expression. Cardiovascular phenotypes displayed by transgenic mice included myocardial hypertrophy and hypotension. Indicative of cardiac hypertrophy, transgenic mice displayed an increased heart to body weight ratio, which was confirmed by the echocardiographic finding of an increased thickness of the interventricular septum and posterior wall. Functional deficits included an increased isovolumetric relaxation time, a decreased heart rate, and cardiac output. Transgenic mice were hypotensive and exhibited a decreased pressor response. Vasoconstrictory regulation by alpha(1B)AR was absent as shown by the lack of phenylephrine-induced contractile differences between ex vivo mesenteric artery preparations. Plasma epinephrine, norepinephrine, and cortisol levels were also reduced in transgenic mice, suggesting a loss of sympathetic nerve activity. Reduced catecholamine levels together with basal hypotension, bradycardia, reproductive problems, and weight loss suggest autonomic failure, a phenotype that is consistent with the multiple system atrophy-like neurodegeneration that has been reported previously in these mice. These results also suggest that this receptor subtype is not involved in the classic vasoconstrictory action of alpha(1)ARs that is important in systemic regulation of blood pressure.

Quantitative imaging in live human cells reveals intracellular alpha(1)-adrenoceptor ligand-binding sites.

Cellular distribution and binding characteristics of native alpha(1)-adrenoceptors (ARs) were determined in a live, single, human smooth muscle cell (SMC) with confocal laser scanning microscopy and a fluorescent ligand, BODIPY-FL prazosin (QAPB). This allowed single-cell competitive ligand binding and showed that 40% of alpha(1)-AR-binding sites in native cells are intracellular. QAPB had high affinity and acted as a nonselective, competitive antagonist versus [(3)H]prazosin at cloned human alpha(1a)-, alpha(1b)-, and alpha(1d)-AR subtypes on membrane preparations and whole cells. RS100329 had 70-fold selectivity for alpha(1a)-ARs versus alpha(1b)- and alpha(1d)-ARs, validating its use to identify this subtype. In similar cells QAPB-associated fluorescence provided quantitative data analogous and comparable to [(3)H]prazosin binding in whole cells. In human, dissociated, prostatic smooth muscle cells QAPB-associated fluorescence binding exhibited specific high-affinity binding properties (FK(D) = 0.63 +/- 0.02 nM), which was 3- to 4-fold higher compared with recombinant cells (FK(D) = 2. 1-2.3 nM). Internal consistency in the data showed that affinity is greater, in general, in membrane preparations than in cells but also greater in the native prostatic tissues or cells than in equivalent recombinant receptors. Fluorescence revealed binding sites both on the plasmalemmal membrane and on intracellular compartments: at all locations RS100329 inhibited QAPB binding identifying the sites as alpha(1A)-ARs. Quantitative three-dimensional mapping of QAPB-associated fluorescence binding in native human cells showed that 40% of high-affinity-binding sites was in intracellular compartments. This provides a potential new site for physiological agonism and makes intracellular access a potential differentiator of drug action.

Single-cell recombinant pharmacology: bovine alpha(1a)-adrenoceptors in rat-1 fibroblasts release intracellular ca(2+), display subtype-characteristic agonism and antagonism, and exhibit an antagonist-reversible inverse concentration-response phase.

Phe-activated Ca(2+) signals recorded from single rat-1 fibroblasts stably expressing the bovine alpha(1a)-adrenoceptor (AR) were characterized and used to analyze functional agonist-antagonist interactions. The response to Phe was initiated by the mobilization of stored Ca(2+) and subsequently sustained by receptor-regulated Ca(2+) influx. The selective alpha(1A)-AR agonist (R)-A-61603 was 141-fold more potent as an agonist than Phe. This potency ratio was consistent with the pharmacology of the native alpha(1A)-ARs. Functional responses evoked by concentrations of Phe of more than 0. 3 microM displayed fade, which could be explained by agonist-dependent depletion of Ca(2+) stores. The antagonists tested did not conform to the predictions of the Schild equation for competitive antagonism as expected from the nonequilibrium nature of the response. The antagonist potency series WB4101 > or = prazosin >> BMY7378, however, was consistent with alpha(1A)-ARs. Antagonism exhibited by WB4101 and prazosin was compatible with a model in which antagonists dissociate so slowly from the receptor that this is a major factor in their inhibition of the transient agonist-mediated response, leading to the appearance of insurmountable antagonism. A consequence of this phenomenon was that an inverse concentration-response relationship at high agonist concentrations was abolished by low concentrations of antagonists. Overall, the results indicate that quantitative pharmacology can be studied successfully in single cells even though equilibrium could not be achieved in the agonist-antagonist-response relationship in this particular cell phenotype. The study also showed a form of fade that could be readily explained.

Measurements of vascular remodeling by confocal microscopy.

The introduction of myographs was crucial for the study of structure and function of resistance arteries. The ability to support and maintain small blood vessels paved the way for true microscopic studies of the vascular cells. However, even after decades of study, we still do not know very much about the "normal" arrangement of smooth muscle cells in the vascular wall and how their distribution affects function. It was clearly time for the next technological step forward. We have shown here how the combination of myography and confocal microscopy creates a platform for the study of vascular structure at the cellular level and in 3D. In addition, the possibility of using live myograph-mounted vessels in combination with LSCM opens a new field of research to assess vascular remodeling from a physiological point of view and to study vascular function at a level not achieved by any other method at present. Now that the hardware is in place it is time to concentrate on the software and improve the methods of analysis. We have used 2D analysis of 3D data sets to describe differences in vascular structure and, at the same time, developed methods to semiautomate the process. The success of the 3D methods will ultimately depend on the reliability and accuracy of the analysis routines. There are still problems to overcome en route to finding a complete solution. However, we believe that the search for a robust fully (or semi-) automated method of 3D analysis will be more than worthwhile. We have defined vascular remodeling to include any changes in cellular arrangement or morphology. However, on a more subtle level, changes in receptors, enzymes, and proteins leading to altered functionality could also be regarded as remodeling. In that respect it may be interesting to map the distribution of the many receptors, channels, and proteins that regulate vascular growth, death, and function. Currently, there is a growing list of fluorescent ligands and antibodies that can be used in conjunction with confocal microscopy. It is possible that multiple stains could be used and imaged at different wavelengths with a view to constructing full 3D models of various structures and their colocalization. It is our belief that the confocal approach will prove to be a major tool in unraveling the complexities of cell-cell interactions and arrangements and will allow a better understanding of the process of vascular remodeling and function.

Importance of agonists in alpha-adrenoceptor classification and localisation of alpha1-adrenoceptors in human prostate.

alpha-Adrenoceptor blocker drugs are commonly used in the clinical (non-surgical) treatment of BPH. alpha1-adrenoceptors were originally sub-divided using agonists but, subsequently, were sub-divided using only antagonists in ligand-ligand interactions, which did not require agonists at all. Ultimately, proof that adrenoceptors are functional receptors for the natural ligands, noradrenaline and adrenaline, requires that agonists be used. The earlier excitement engendered by finding varying agonist potency series in different tissues has not been revisited to place it in the context of current concepts of alpha1-adrenoceptor subtypes. This review will consider the advantages and limitations of different agonists for the study of alpha1-adrenoceptor subtypes including 'extreme' examples where the archetypal alpha1-adrenoceptor agonist phenylephrine activates alpha2-adrenoceptors and others where UK14304, often the alpha2-adrenoceptor agonist of choice, activates alpha1-adrenoceptors. New work will also be presented showing the interaction between agonists and the fluorescent alpha1-adrenoceptor antagonist QAPB. This introduces the novel point of view of studying the displacement of antagonists by agonists. Possible errors in antagonist classification arising from complexity in the actions of agonists and the recently developed method of fluorescent ligand binding on isolated living human prostatic smooth muscle cells will be discussed.

Pharmacological implications of cellular localization of alpha1-adrenoceptors in native smooth muscle cells.

1. This study examines the cellular localization of alpha1-adrenoceptors and demonstrates that binding to intracellular receptive binding sites in native smooth muscle cells may influence the pharmacological profile of agonists or antagonists. The example tissue studied was rat basilar artery. 2. An alpha1-adrenoceptor antagonist and fluorescent analogue of prazosin, BODIPY-FL prazosin (QAPB) allowed visualization, with high resolution, of both plasma membrane and cytosolic binding sites on live native cells, as previously shown in cells harbouring recombinant receptors. QAPB-associated fluorescence binding was both time- and concentration-dependent in rat basilar smooth muscle cells and affinity for alpha1-adrenoceptors was calculated from specific binding curves as 1.1 nM. 3. Concentration-dependent binding of QAPB detected in smooth muscle cells dissociated from rat basilar arteries was composed of diffuse and clustered fluorescence. Visually the diffuse component of fluorescence was the more evident up to a concentration of 5 nM QAPB. Confocal visualization of an optical section through the cell showed that the clustered component was located mainly intracellularly. In rat basilar artery smooth muscle cells the intracellular binding sites were located in close proximity to the nuclear membrane. 4. 3D models of QAPB-associated fluorescence demonstrate that a high proportion of effective binding sites are intracellular, showing not only that a high proportion of receptors are located inside the cell but also that in this location they can bind ligands. This has implications for pharmacological analysis in relation to the consequences of intracellular binding per se and for differential effects upon the pharmacology of particular ligands according to whether they can enter the cell.

Cellular localization and pharmacological characterization of functioning alpha-1 adrenoceptors by fluorescent ligand binding and image analysis reveals identical binding properties of clustered and diffuse populations of receptors.

A fluorescent quinazoline derivative was shown to retain high affinity for, and act as a competitive antagonist at, alpha-1 adrenoceptors. This allowed it to be used in live cells to localize receptors and to quantify receptor binding characteristics. The technique was demonstrated and validated on fibrobasts transfected with a recombinant alpha-1d adrenoceptor. Using confocal laser scanning microscopy and image analysis methods both diffuse and clustered binding sites were found: their binding characteristics were assessed and found comparable to radioligand binding on membrane preparations. This approach should have widespread applicability in nonradioactive assays determining the location, quantity and binding properties of receptors and other biological molecules on live tissue.

Confocal microscopic characterization of a lesion in a cerebral vessel of the stroke-prone spontaneously hypertensive rat.

BACKGROUND AND PURPOSE: Hypertension is a major risk factor for stroke and is associated with alterations in vascular structure and function. The aim of this study was to determine vascular function, wall morphology, and vascular smooth muscle cell (VSMC) arrangement in basilar arteries from stroke-prone spontaneously hypertensive rats (SHRSP) and normotensive control strain Wistar-Kyoto rats (WKY). The effect of perindopril treatment on SHRSP structure and function was also assessed. METHODS: VSMC orientation was determined with laser-scanning confocal microscopy and computer-assisted image processing in basilar arteries stained with 5(6)-carboxyfluorescein (wavelengths: excitation, 488; emission, 515) or propidium iodide (excitation, 529; emission, 550). Measurements of wall morphology and functional responses to serotonin and KCl were assessed with wire myography. RESULTS: In the WKY basilar arteries, VSMCs were uniformly oriented perpendicular to the longitudinal axis of the vessel, whereas in the SHRSP there were localized foci of VSMC geometric disorganization, with a significant deviation from 90 degrees. The SHRSP basilar arteries also showed structural remodeling and reduced contractile responses to serotonin and KCl. Perindopril treatment normalized blood pressure, prevented wall morphology alterations, and improved function but had no effect on VSMC disorganization. CONCLUSIONS: This is the first demonstration of lesions of VSMC geometric disorganization in a cerebral artery from a stroke-prone genetically hypertensive rat strain. These structural abnormalities are independent of blood pressure. Their functional sequel may play a role in the pathogenesis of stroke in this model.

Confocal microscopy for structure and real-time pharmacology in blood vessels.

The structure and composition of living small blood vessels can be studied in great detail in three dimensions using confocal microscopy. Individual cells and their components can be visualised by vital dyes for the nucleus, cytoplasm or extracellular space. Specific ligands can then localise individual components such as membrane receptors with great precision. Cell function is unaffected, allowing the study, in real time, of the changing relation and contribution to vascular contraction or dilatation of different cell types particularly smooth muscle, endothelium and adventitia. This allows not only visualisation but quantification, using image analysis software. These techniques will be of particular value in assessing the contribution of form to function in pathological situations such as vascular remodelling in hypertension.

The relationship between the adrenoceptor and nonadrenoceptor-mediated effects of imidazoline- and imidazole-containing compounds.

This article brings together work on imidazoline or imidazole-containing compounds concerned with the pharmacology of alpha-adrenoceptors, principally on smooth muscle, to illustrate how imidazolines have contributed to the subclassification of alpha-adrenoceptors and how, against this background, attempts have been made to use this knowledge to uncover "nonadrenoceptor"-mediated biological effects of previously uncharacterized compounds, notably imidazole-containing dipeptides and "clonidine displacing substance" (CDS). Recent data are included on (1) the pharmacology of UK-14304, (2) nonadrenoceptor actions of phentolamine, (3) the pharmacology of tissue extracts containing imidazole-containing dipeptides and CDS activity, and (4) ligand binding data at I1 and I2 sites.