Abstract
S1P1 (sphingosine-1-phosphate receptor 1) agonists prevent lymphocyte egress from secondary lymphoid organs and cause a reduction in the number of circulating blood lymphocytes. We hypothesized that S1P1 receptor modulators with pathway-selective signaling properties could help to further elucidate the molecular mechanisms involved in lymphocyte trapping. A proprietary S1P1 receptor modulator library was screened for compounds with clear potency differences in β-arrestin recruitment and G protein alpha i subunit (Gαi) protein-mediated signaling. We describe here the structure-activity relationships of highly potent S1P1 modulators with apparent pathway selectivity for β-arrestin recruitment. The most differentiated compound, D3-2, displayed a 180-fold higher potency in the β-arrestin recruitment assay (EC50 0.9 nM) compared with the Gαi-activation assay (167 nM), whereas ponesimod, a S1P1 modulator that is currently in advanced clinical development in multiple sclerosis, was equipotent in both assays (EC50 1.5 and 1.1 nM, respectively). Using these novel compounds as pharmacological tools, we showed that although a high potency in β-arrestin recruitment is required to fully internalize S1P1 receptors, the potency in inducing Gαi signaling determines the rate of receptor internalization in vitro. In contrast to ponesimod, the compound D3-2 did not reduce the number or circulating lymphocytes in rats despite high plasma exposures. Thus, for rapid and maximal S1P1 receptor internalization a high potency in both Gαi signaling and β-arrestin recruitment is mandatory and this translates into efficient reduction of the number of circulating lymphocytes in vivo.
Introduction
Sphingosine-1-phosphate (S1P) is a bioactive sphingolipid that causes pleiotropic cellular effects, including cell proliferation, migration, and survival, by acting as an intracellular or extracellular mediator. Extracellular S1P signaling is mediated by five different S1P receptor subtypes, named S1P1 through S1P5 receptors, which show differential expression across a variety of tissues and cell types. Synthetic S1P1 receptor modulators, such as the nonselective S1P1,2,3,4,5 receptor modulator fingolimod (FTY720/Gilenya) or the selective S1P1 receptor modulator ponesimod block lymphocyte egress, leading to rapid and reversible lymphopenia, a property that is used as a mechanistic basis to treat autoimmune conditions (Hla and Brinkmann, 2011; Piali et al., 2011). Lymphocyte egress from secondary lymphoid organs into lymph is dependent on their expression of S1P1 receptor that allows them to chemotax along the S1P gradient (Allende et al., 2004; Matloubian et al., 2004), which is formed by high S1P concentrations in blood and lymph and generally low concentrations in tissues (Spiegel and Milstien, 2003). Even though synthetic compounds activate S1P1 receptors, it has been suggested that they act in fact as functional antagonists, causing rapid and sustained receptor internalization and degradation, thus abolishing the lymphocytes’ ability to sense and migrate along the S1P gradient (Hla and Brinkmann, 2011; Gatfield et al., 2014). This hypothesis is supported by the fact that S1P1 antagonists are also able to induce lymphopenia in vivo (Tarrasón et al., 2011; Quancard et al., 2012). However, it was recently reported that the synthetic agonist BMS-986104 was able to induce lymphopenia without showing complete internalization of S1P1 receptors (Dhar et al., 2016) and a transgenic mouse, expressing internalization-defective S1P1 receptors, still showed FTY720-induced lymphopenia, albeit with delayed kinetics (Thangada et al., 2010). Previous reports had suggested S1P1 agonism to be a mechanism responsible for lymphocyte egress inhibition induced by synthetic agonists and S1P1 agonism could in fact disrupt the S1P gradient, thus blinding the lymphocytes to the exit. The fact that the blockade of S1P lyase activity, the enzyme responsible for S1P gradient formation, leads to lymphocyte sequestration (Weiler et al., 2014) supports this hypothesis. Alternatively, synthetic compounds could activate S1P1 receptors on lymphatic endothelial cells, leading to the tightening of cell-cell junctions and thus blocking lymphocyte exit. It has been shown that S1P1 agonist 5-[4-phenyl-5-(trifluoromethyl)-2-thienyl]-3-[3-(trifluoromethyl)phenyl]-1,2,4-oxadiazole (SEW2871), which causes transient S1P1 internalization and recycling, reduced T cell egress in lymph node explants within 5 minutes, suggesting it closed normally open stromal gates (Sanna et al., 2006). Therefore, the individual contribution of functional antagonism or agonism leading to synthetic S1P1 receptor modulator-induced lymphopenia is far from being fully understood.
Recently, it was shown that chaperone-dependent presentation of the natural ligand S1P shows differences in S1P1 receptor engagement and signal transduction, leading to distinct physiologic responses. In particular, high-density lipoprotein-S1P was shown to induce association of S1P1 receptors with β-arrestin 2, which has an anti-inflammatory activity, whereas albumin-S1P led to suppression of forskolin-induced cAMP but did not induce formation of S1P1 receptor/β-arrestin complexes (Galvani et al., 2015). The attractive concept of biased agonism, which posits that ligands can stabilize different G protein-coupled receptor conformation states to induce individual intracellular signaling pathways (Luttrell et al., 2015), may offer a theoretical framework for the observed effects. In addition, considering that the natural ligand, depending on the way it is presented to the S1P1 receptor, displays biased agonism and induces different pharmacological behaviors, suggested that similar properties might be discovered in synthetic S1P1 receptor modulators. Such compounds could serve as valuable tools to further investigate S1P1 receptor modulator-induced pharmacology at a signaling pathway level.
Here, we describe the identification and structure-activity relationship of compounds with novel and unique S1P1 receptor signaling characteristics. We established sensitive in vitro assays to quantify kinetic responses that are induced upon S1P1 receptor activation and demonstrated that these novel compounds show an apparent deficiency in G protein alpha i subunit (Gαi) signaling, while retaining β-arrestin recruitment with high potency and efficacy, leading to effective S1P1 receptor internalization and degradation. Using cellular assays in recombinant and primary human lymphatic endothelial cells, we determined that Gαi signaling influenced the rate of S1P1 receptor internalization, whereas β-arrestin recruitment was necessary for effective internalization. In vivo, these novel S1P1 receptor modulators displayed a delayed onset lymphopenia, a striking pharmocokinetic/pharmacodynamics disconnect, and surprisingly they were no longer able to induce fully efficient lymphopenia. These results suggest that both Gαi protein signaling and β-arrestin recruitment are necessary to induce rapid S1P1 receptor internalization, leading to efficient lymphocyte reduction by S1P1 modulators in vivo.
Materials and Methods
Materials.
S1P was purchased from Avanti Polar Lipids, Inc (Alabaster, AL). Ponesimod [(Z,Z)-5-[3-chloro-4- (2R)-2,3-dihydroxy-propoxy)-benzylidene]-2- propylimino-3-o-tolylthiazolidin-4-one] was synthesized by Actelion Pharmaceuticals Ltd (Allschwil, Switzerland). SEW2871 was purchased from Cayman Chemical. All other S1P1 receptor modulators described herein were synthesized by Actelion Pharmaceuticals Ltd. Human lung lymphatic microvascular endothelial cells (HMVEC-LLy) were purchased from Lonza (Verviers, Belgium). Tango EDG1-bla U2OS cells were obtained from Invitrogen (Carlsbad, CA).
EPIC Assay.
In this study, 10,000 Chinese hamster ovary cells stably expressing hS1P1 receptor were seeded in 384-well EPIC sensor microplates (Corning; Corning, NY) and grown for 24 hours in Ham’s F12 medium supplemented with 10% charcoal-treated fetal bovine serum, 300 µg/ml geneticin, 100 U penicillin, and 1 µg/ml streptomycin. The medium was removed, the wells were filled with 40 µl assay buffer [Hanks’ balanced salt solution with 20 mM Hepes, 0.05% fatty acid-free bovine serum albumin (fafBSA) and 2% dimethylsulfoxide (DMSO)], and the plate was loaded in the EPIC reader (Corning) for 2-hour equilibration. After the baseline dynamic mass redistribution measurement, 10 µl of test compounds in assay buffer were added and real-time dynamic mass redistribution changes were recorded for 30 minutes. The end data from EPIC Analyzer software (Corning) were exported to Microsoft Excel and used to determine compound potency with the IC50 Witch software (Actelion Pharmaceuticals Ltd.) using the following settings: minimum defined by the vehicle control (DMSO), maximum defined by the maximal response of the compound (smart max), no weighting, and variable slope.
β-Arresting Recruitment Assay.
In this study, 5000 Tango EDG1-bla U2OS cells were plated in 30 µl FreeStyle Expression Medium (Life Technologies, Carlsbad, CA) in black, clear-bottom 384-well plates and stimulated with 10 µl of test compounds for 16 hours at 37°C in a humidified CO2 incubator. Cells were then loaded with LiveBLAzer-FRET B/G substrate (Life Technologies) for 2 hours at room temperature in the dark and the fluorescence emissions at 460 and 530 nm were measured with SynergyMX reader (BioTek, Winooski, VT) using 409 nm excitation filter. Following background subtraction from both channels, the 460/530 nm emission ratio for each well was calculated and used to determine compound potency with the IC50 Witch software (Actelion Pharmaceuticals Ltd.) using the following settings: minimum defined by the vehicle control (DMSO), maximum defined by the maximal response of the compound (smart max), no weighting, and variable slope.
SNAP-S1P1 Receptor Internalization Assay.
In this study, 30,000 HeLa cells stably expressing hS1P1 receptor with the N-terminal SNAP-tag (HeLa-SNAP-hS1P1) were seeded in gelatin-coated, black, clear-bottom 384-well plates and grown for 24 hours in RPMI 1640 medium supplemented with 10% fetal bovine serum, 1 mg/ml geneticin, 100 U penicillin, and 1 µg/ml streptomycin. The medium was changed to 60 µl starvation medium (RPMI 1640 with 0.1% fafBSA, 100 U penicillin, and 1 µg/ml streptomycin) and incubated at 37°C in a humidified CO2 incubator before addition of 20 µl of test compounds. After incubation with compounds for the indicated times, the medium was removed and the SNAP-tagged surface S1P1 receptors labeled with SNAP-surface Alexa Fluor 488 substrate (1 µM; New England Biolabs, Ipswich, MA) in starvation medium for 20 minutes at 37°C. The cells were washed with ice-cold starvation medium and incubated for 30 minutes at 4°C in the dark. The medium was changed again to 20 µl ice-cold starvation medium, and the fluorescence of the SNAP-labeled surface S1P1 receptors was measured at 506 nm excitation and 526 nm emission with SynergyMX reader (BioTek). The data were used either to calculate the percentage of S1P1 receptor internalization or to determine compounds’ potency at 16 hours with the IC50 Witch software (Actelion Pharmaceuticals Ltd.) using the following settings: maximum defined by the vehicle controls (DMSO, 0% internalization), minimum defined by the negative controls (empty HeLa cells, 100% internalization), no weighting, and variable slope.
Immunofluorescence Microscopy.
In this study, 50,000 HMVEC-LLy were seeded into gelatin-coated eight-chamber slides (BD Falcon, Bedford, MA) and grown for 48 hours in EGM-2MV medium (Lonza). After serum starvation for 4 hours, the test compounds were added and incubated for the indicated times. Cells were fixed (4% paraformaldehyde), permeabilized with 0.1% Triton X-100, and stained in phosphate-buffered saline, 1% bovine serum albumin using rabbit anti-hS1P1 receptor antibodies (Santa Cruz Biotechnology, Dallas, TX) and Alexa Fluor 546 goat anti-rabbit antibodies (Life Technologies). Nuclei were stained with Hoechst 33342 (Life Technologies) and F-actin with Alexa Fluor 488 phalloidin (Life Technologies). Images were acquired with the Axiovert 200 fluorescence microscope (Zeiss, Jena, Germany).
ERK and Akt Activation Assay.
In this study, 10,000 HMVEC-LLy were seeded in gelatin-coated 12-well plates and grown for 48 hours in EGM-2MV medium (Lonza). After serum starvation for 4 hours, the test compounds were added and incubated for the indicated times. Cells were washed with ice-cold phosphate-buffered saline and lysed in radioimmunoprecipitation assay lysis buffer (Sigma, St. Louis, MI) supplemented with 10 mM NaF, 4 mM sodium orthovanadate, 1 mM phenylmethanesulfonyl fluoride, 1 mM dithiothreitol, and 100 U/ml benzonaze. Equal protein amounts were separated on 4%–12% Bis-Tris polyacrylamide gel (Life Technologies) and transferred to nitrocellulose membranes for immunobloting. Phosphorylated ERK1/2, total ERK1/2, phosphorylated Akt, and total Akt were detected with rabbit anti-phospho-p44/42 mitogen-activated protein kinase (Cell Signaling Technology, Danvers, MA), anti-mitogen-activated protein kinase 1/2 (Merck Millipore, Temecula, CA), anti-phospho-Akt (Ser473) (Cell Signaling Technology), and anti-Akt (Cell Signaling Technology) antibodies, respectively. As a secondary reagent, horseradish peroxidase–linked donkey anti-rabbit antibodies (Amersham Biosciences, Little Chalfont, UK) were used. The Plus-ECL chemiluminescence detection substrate (Perkin Elmer, Groningen, The Netherlands) was used for detection. Comparative densitometry of immunoblots was performed on LAS400 imager (Fujifilm) using the Multi Gauge software (Fujifilm, Dusseldorf, Germany).
HMVEC-LLy Chemotaxis Assay.
HMVEC-LLy specimens were serum starved for 2 hours and then labeled with Calcein-AM (5 µg/ml; Life Technologies) for 30 minutes. The labeled cells were washed and resuspended in EBM-2 medium (Lonza) supplemented with 0.1% fafBSA (Sigma) at 400,000 cells/ml. 50 µl cell suspensions were added to the top chamber of 96-well 8 µm FluoroBlok inserts (Corning) and combined with the bottom chambers containing 220 µl test compounds in EBM-2 medium supplemented with 0.1% fafBSA. The plate was placed at 37°C in a humidified CO2 incubator and the fluorescence of the migrated cells in the lower wells was measured after a given time (45 minutes and 2, 3, and 4 hours) at 485 nm excitation and 530 nm emission on a Cytofluor 4000 (Perseptive Biosystems, Framingham, MA).
Measurement of Lymphocyte Count.
Lymphocyte count was performed in male Wistar rats weighing 294–510 g (Harlan Laboratories Inc., Itingen, Switzerland). The rats were housed in climate-controlled conditions with a 12-hour light/dark cycle with free access to normal pelleted chow (Provimi Kliba SA, Kaiseraugst, Switzerland) and water ad libitum. The rats were used for blood sampling after an acclimatization period of at least 7 days. All rats were housed in Makrolon cages (Indulab, Gams, Switzerland) with wire mesh tops and standardized softwood bedding and appropriate environmental enrichment. The compounds were first dissolved in 100% DMSO and then diluted to the appropriate concentration in 7.5% gelatin; solutions were protected from light. The final concentration of DMSO in the formulation was 5%. Peripheral blood lymphocyte count was assessed by hematology following single oral (gavage) dose of 10 mg/kg compound (n = 6/group) or vehicle (n = 6/group). Blood samples from rats were collected before and at 3, 6, and 24 hours after oral administration of compound or its vehicle by sublingual puncture. Blood (0.5 ml) was drawn into tubes containing 5% EDTA. For the determination of blood lymphocyte count, undiluted blood was analyzed using a 5diffCP Hematology Analyzer (Beckman Coulter, Brea, CA).
Measurement of Compound Concentrations in Plasma.
Plasma was separated by centrifugation and stored at −20°C. Compound concentrations in plasma samples were determined using liquid chromatography coupled to mass spectrometry.
Ethics Statement.
All animal experimental procedures were conducted in accordance with the Swiss animal welfare ordinance and Actelion Animal Welfare policy on the use of experimental animals. The studies were approved by the Baselland Cantonal Veterinary Home Office.
Statistical Analysis.
For statistical analysis, one-way analysis of variance with Dunnett’s post hoc test was performed. When the P value was <0.05, the results were considered significant (GraphPad Prism 7 Software; GraphPad, San Diego, CA).
Results
Synthetic S1P1 Receptor Agonists with Different Potencies in Gαi Signaling and β-Arrestin Recruitment.
To reveal potential differences in synthetic S1P1 receptor agonist-induced signaling and to explore the possible consequences on lymphocyte trafficking in vivo, we first established sensitive in vitro assays to quantify kinetic responses of Gαi protein-mediated and β-arrestin-mediated S1P1 receptor signaling. A label-free resonant waveguide grating assay (EPIC) was developed to measure in real-time Gαi protein-mediated responses in recombinant Chinese hamster ovary hS1P1 cells (Nayler et al., 2010). The S1P-induced EPIC signal increased rapidly and peaked 6–12 minutes after ligand addition. The signal subsequently decreased, and for lower S1P concentrations reached baseline within 25 minutes after addition (Fig. 1A). The S1P-induced EPIC response was efficiently blocked with the Gαi protein inhibitor pertussis toxin or the selective S1P1 receptor antagonist TASP0277308 (Fujii et al., 2012) (Supplemental Fig. 1), demonstrating that the observed responses in this assay were S1P1 receptor specific and Gαi protein-mediated.
To assess S1P1 receptor internalization kinetics, recombinant HeLa cells with stable expression of a SNAP-tagged-hS1P1 receptor construct were employed using a fluorescence-based readout. In this assay, ponesimod (Bolli et al., 2010) led to a potent and sustained 80%–90% reduction of cell surface residing S1P1 receptors after 1 hour (EC50 ∼8 nM) (Fig. 1B), which confirmed our previous results using fluorescence-activated cell sorting (Gatfield et al., 2014). β-Arrestin recruitment to the S1P1 receptor was assessed using the Tango EDG1-bla-U2OS cell reporter gene assay and was quantified 16 hours after compound addition (Wetter et al., 2009). The Tango-based assay potencies of a selection of synthetic S1P1 receptor agonists correlated very well with the potencies that were observed with the SNAP-tagged-hS1P1 receptor internalization assay 16 hours after ligand addition (Supplemental Fig. 2A), supporting that β-arrestin recruitment and receptor internalization were functionally linked. As expected, the S1P1 agonist-induced responses at 16 hours in both assays, i.e., Tango and SNAP-tag, were insensitive to pertussis toxin treatment (Supplemental Fig. 2, B–E), suggesting that receptor internalization and β-arrestin recruitment could be uncoupled from Gαi protein signaling.
The EPIC and Tango-β-arrestin assays were then used in parallel to screen a collection of proprietary synthetic S1P1 receptor modulators. The prototypic synthetic S1P1 receptor agonists ponesimod (Bolli et al., 2010) and SEW2871 (Sanna et al., 2004) were also included in this screen. Interestingly, we identified a small subset of compounds that induced potent and efficient β-arrestin recruitment, but in contrast to the majority of compounds, including ponesimod and SEW2871, displayed clearly slower kinetics and lower potencies in inducing Gαi protein-mediated signaling within 30 minutes in the EPIC assay. While ponesimod and SEW2871 at high concentrations (≥80 nM) reached their half-maximal signal within 7–9 minutes (Fig. 2, A and B), the compound D3-2 required 14–15 minutes, and after 30 minutes it remained considerably less potent (Fig. 2, C and D).
Interestingly, a consistent structure-activity relationship could be established around these compounds (Table 1). The residue attached to position five of the thiophene moiety (R1) differentially influenced the compound’s potency in the two assays. In general, a small substituent-like hydrogen or methyl led to compounds with higher potency in the Gαi signaling assay, while larger groups such as an iso-butyl chain or a cyclopentane ring gave compounds with a preference for β-arrestin recruitment. This preference for β-arrestin recruitment was further enhanced when the two methyl groups in R2 were replaced by two ethyl groups. In contrast, the nature of the side chain attached to the phenyl ring of the tri-aryl scaffold appeared to have little impact on the compound’s signaling preference.
Hence, chemical optimization led to compounds with near 100-fold potency difference between Gαi protein-signaling (EPIC assay) and β-arrestin recruitment (Tango assay), like compounds C2-2, C3-2, or D3-2 (Table 1). The apparent lower potency in Gαi protein-mediated signaling by these compounds was confirmed in classic GTPγS assay (Supplemental Table 1). This apparent deficiency in Gαi signaling did not compromise the activity of the compounds to internalize the S1P1 receptor within 16 hours (Table 2) nor did it prevent S1P1 receptor degradation (Supplemental Fig. 3). These uniquely differentiated compounds were in terms of their functional profiles more similar to ponesimod, which potently activated Gαi signaling, β-arrestin recruitment, internalization, and degradation (Supplemental Fig. 3; Table 2) (Bolli et al., 2010; Gatfield et al., 2014) than to SEW2871, which potently activated Gαi signaling, but was >20-fold less potent than ponesimod in β-arrestin recruitment and S1P1 internalization (Table 2) and induced only limited degradation of S1P1 (González Cabrera et al., 2007). Thus, based on these data it appears that a high potency in β-arrestin recruitment is mandatory to achieve substantial receptor internalization and degradation.
Gαi Protein-Coupling Deficient S1P1 Agonists Can Maximally Internalize S1P1 Receptors but at a lower Rate.
We next studied the kinetics of S1P1 receptor internalization and investigated representative compounds with different Gαi protein signaling and β-arrestin recruitment potencies (ponesimod, D2, D3, D3i, D3-2, and SEW2871) at different concentrations using the SNAP-tagged-hS1P1 receptor assay. The amount of internalized S1P1 receptor was measured at different times for up to 20 hours after compound addition (Fig. 3). At the highest concentration (1 µM), which was well above the EC50 values of all compounds in Gαi protein signaling and β-arrestin assays, there was no obvious difference in the rate or magnitude of S1P1 receptor internalization and all compounds induced almost 100% internalization within 4–6 hours after compound addition (Fig. 3, A and D). However, at lower concentrations (i.e., 100 and 30 nM) different internalization rates were apparent (Fig. 3, B–D). Compounds D3i and D3-2 with the lowest potencies in Gαi protein signaling (EC50 63.3 and 167.9 nM, respectively), and similar β-arrestin potencies (EC50 0.7 and 0.9 nM, respectively) displayed the slowest rate of S1P1 receptor internalization among these compounds (Fig. 3D). Eventually, maximal S1P1 receptor internalization was reached at all investigated concentrations, but only after prolonged incubation times. In contrast, SEW2871 always reached a plateau after 4–6 hours; the magnitude of effect was dose dependent and close to maximal internalization was reached at 1 µM. These experiments demonstrate that although a high potency in the β-arrestin assay is required to fully internalize the S1P1 receptors, the potency in the Gαi signaling assay actually determines the rate of S1P1 receptor internalization. Thus, for rapid and maximal S1P1 receptor internalization a high potency in the Gαi signaling and in the β-arrestin assay is mandatory.
S1P1 Receptor Signaling in Lymphatic Endothelial Cells.
S1P1 receptor activation is known to induce ERK1/2 and Akt phosphorylation (Igarashi et al., 2001), as well as induce cell chemotaxis through activation of Gαi protein signaling (Wang et al., 1999). We thus investigated these effects in human lymphatic endothelial cells (HMVEC-LLy) to further characterize the signaling properties of the newly identified compounds in a physiologically relevant, human, and nonrecombinant cell system.
HMVEC-LLy were treated with 1 µM of two of the most differentiated agonists D3i and D3-2, or ponesimod, and phosphorylated ERK and Akt were measured in cell extracts. Phosphorylation of ERK1/2 and Akt induced by ponesimod was maximal at 5 minutes after stimulation and decreased to basal levels within 30 minutes (Fig. 4). The phosphorylation induced by D3i was delayed and reached a maximum at 15 minutes after stimulation (Fig. 4, C and F), while the compound D3-2, which was 180-fold more potent in the β-arrestin than in the Gαi signaling assay, was highly inefficient in inducing ERK1/2 and Akt phosphorylation for up to 30 minutes. Furthermore, ponesimod potently induced HMVEC-LLy chemotaxis in a dose-dependent manner (Fig. 5), whereas the compounds D2, D3, and D3i were clearly less potent, which was in line with their loss of potency in the Gαi protein signaling assay. Compound D3-2 was only able to induce HMVEC-LLy chemotaxis at 10 µM concentration, confirming its inefficient Gαi signaling. This compound did not significantly increase chemotaxis of HMVEC-LLy for up to 4 hours (data not shown).
Next, ponesimod, D3i, and D3-2 were compared in regard of their ability to internalize S1P1 receptors in HMVEC-LLy cells. To this end, HMVEC-LLy were incubated for different times with these compounds (1 µM), followed by immunofluorescence staining of S1P1 receptors. As shown in Fig. 6, ponesimod already induced strong S1P1 receptor translocation from the cell surface into intracellular compartments after 15 minutes of incubation. S1P1 internalization induced with compounds D3i and D3-2 was clearly slower compared with ponesimod, but after 2 hours there was a much smaller difference observed between the three agonists, only compound D3-2 seemed to be slightly less efficient at this time point. No compound differences were apparent after 24 hours of incubation, corroborating the observations in recombinant S1P1 receptor-expressing HeLa cells. Altogether, these results show that also in native human cells S1P1 receptor internalization can be induced by synthetic agonists, even by those with Gαi signaling deficiencies, albeit at a clearly lower rate. However, high potency in Gαi protein signaling is required to strongly activate additional (intra)cellular responses, such as ERK and Akt phosphorylation or cell chemotaxis.
Reduction of Peripheral Lymphocyte Counts In Vivo.
Efficient S1P1 receptor internalization and consequently functional antagonism has been proposed as a mechanistic basis for the observed reduction of the number of circulating blood lymphocytes upon administration of synthetic S1P1 modulators in vivo. Since we could not observe major differences in the magnitude of S1P1 internalization in vitro between ponesimod and compounds with attenuated Gαi protein signaling, we tested the ability of these novel compounds to induce lymphopenia in vivo. To this end, we used single oral administration (10 mg/kg) of each compound in rats and measured blood lymphocyte counts as well as compound plasma concentration 3, 6, and 24 hours later. As expected (Bolli et al., 2010; Piali et al., 2011), ponesimod induced a rapid and significant reduction of circulating lymphocyte counts that reached a plateau 3 hours postdosing (Fig. 7B). The effect remained for at least three additional hours and then almost fully returned to baseline after 24 hours. For ponesimod a good correlation of lymphocyte count reduction and plasma concentration was observed (Fig. 7, A and B). Surprisingly, we observed that compounds with attenuated Gαi signaling but with a similarly high potency in β-arrestin recruitment and S1P1 receptor internalization assays as ponesimod, displayed an obvious disconnect between the pharmacodynamic (Fig. 7B) and pharmacokinetic effects (Fig. 7A). Although the compounds reached similar or even higher plasma exposures compared with ponesimod, the onset of blood lymphocyte count reduction was slower and the maximal effect on the lymphocyte count was reached later. Furthermore, a clear trend to lower maximal lymphocyte count reduction was seen with those compounds compared with ponesimod. A slight trend was already observed for compound D2, but a more pronounced effect was seen with compounds D3 and D3i, which showed a clear delay in the onset of lymphocyte count reduction (6 hours vs. 3 hours) and the plateau was only reached after 24 hours instead of 3 hours, although the plasma concentrations already peaked at 3 hours and were clearly lower after 24 hours. Remarkably, compound D3-2, which is the compound with the most pronounced Gαi protein signaling deficit, already reached very high plasma concentrations after 3 and 6 hours without any obvious signs of lymphocyte count reduction. Moderate lymphocyte count reduction (approximately 20%) was observed only after 24 hours when the plasma concentration was already much lower again. Of note, rat plasma protein binding of compounds D2 to D3-2 was similar. Furthermore, the compounds activated and desensitized rat S1P1 receptors with similar potencies as the human S1P1 receptors, as exemplified by the compound D3-2 (Supplemental Fig. 4). These results suggest that for rapid onset and substantial blood lymphocyte count reduction in vivo, potent Gαi protein signaling and β-arrestin recruitment are both necessary.
Discussion
To current knowledge, S1P1 receptor modulators cause lymphocyte trapping in secondary lymphoid organs, reduce circulating lymphocytes, and attenuate autoimmune disease symptoms in various animal models and humans (Urbano et al., 2013). The absolute requirement for S1P1 receptors mediating lymphocyte exit from lymph nodes has been demonstrated using different genetic and pharmacological approaches. It has been shown that S1P1-deficient lymphocytes cannot egress from thymus or secondary lymphoid organs (Matloubian et al., 2004) and S1P1 heterozygous lymphocytes egress more slowly than wild-type lymphocytes (Lo et al., 2005). Pharmacological blockade of S1P1 receptors with specific antagonists also induces lymphopenia in vivo (Tarrasón et al., 2011; Quancard et al., 2012). Together, this led to the current thinking that S1P1 receptor modulators induce lymphopenia through functional antagonism, following sustained S1P1 receptor internalization and proteasomal degradation (Hla and Brinkmann, 2011). However, with the discovery of SEW2871 it appeared that other mechanisms might also contribute to the induction of lymphopenia, which is so effectively induced by FTY20/fingolimod/Gilenya and other S1P1 receptor modulators, since SEW2871 causes only transient S1P1 receptor internalization and recycling, but is nevertheless lymphopenic in vivo (Jo et al., 2005). For example, lymphatic endothelial cells express high levels of S1P1 receptor and SEW2871 has been shown to rapidly reduce T cell egress in lymph node explants, suggesting its action on stromal gates rather than lymphocytes (Sanna et al., 2006). Therefore, the exact molecular events leading to S1P1 receptor modulator-induced lymphopenia remain to be fully elucidated.
We describe here the discovery of novel synthetic S1P1 receptor modulators with unique pharmacological profiles. We used these compounds as pharmacological tools to better understand the molecular mechanisms leading to lymphopenia. Our screening strategy was built on the recently emerging concept of biased agonism and was specifically aimed at the identification of compounds with deficiency in Gαi protein signaling and preserved potency and efficacy in β-arrestin recruitment and S1P1 receptor internalization. We thus identified novel structure-activity relationships of synthetic S1P1 receptor modulators with significantly reduced potency in Gαi protein signaling and downstream activation of ERK1/2 and Akt, but with fully retained β-arrestin recruitment capacity. Compound D3-2 displayed the most pronounced differential (180-fold potency shift) pathway activation. Compounds with an apparent β-arrestin bias had been previously described in the case of type 1 parathyroid hormone receptors and they demonstrated clearly different pharmacological effects compared with the nonbiased counterparts (Gesty-Palmer et al., 2006). Another well-known example is the angiotensin 1 receptor agonist, TRV120023, which was shown to have different and potentially advantageous effects compared with nonbiased agonists in models of acute cardiac injury (Kim et al., 2012). Together, such examples appear to support the hypothesis that Gα protein-mediated and β-arrestin-mediated signaling is dissociable and triggers distinct pharmacological effects. Similar to most known examples, we have not fully elucidated the exact molecular mechanism, leading to the apparent difference in activities between these assays. The compounds may show preference to stabilize certain G protein-coupled receptor conformations (Pupo et al., 2016), they may influence Gα protein dissociation rates (Furness et al., 2016), or show different thermodynamic properties in G protein-coupled receptor binding (Klein Herenbrink et al., 2016).
Nevertheless, using our novel S1P1 receptor modulators, we were able to demonstrate in vitro that reduced Gαi protein signaling potency with preserved β-arrestin recruitment potency led to a clearly slower S1P1 receptor internalization rate, without compromising S1P1 receptor internalizing and degrading efficacy. With increasing compound concentration and consequently more Gαi protein signaling engagement, the S1P1 receptor internalization rate could be accelerated and the pharmacology became closer to the classical S1P1 receptor modulators, such as ponesimod. Based on the in vitro data and adhering to the idea of functional S1P1 receptor antagonism being responsible for lymphopenia, we thus anticipated a delayed onset of lymphopenia, without major consequences on maximal lymphocyte reduction in vivo. However, S1P1 modulators with increasingly lower Gαi protein signaling potency displayed a clear tendency for delayed lymphopenia, but unexpectedly the maximal lymphocyte count reduction was also significantly compromised. In extremis, D3-2, the compound with the most pronounced potency differences in Gαi protein versus β-arrestin signaling assays barely reduced circulating lymphocytes, despite having plasma exposures exceeding those of all other tested compounds, suggesting a complete pharmacokinetic/pharmacodynamic disconnect. Furthermore, the lack of lymphocyte count reduction cannot be explained by the difference in plasma protein binding or in potency on rat S1P1 receptors. Our data do not exclude that functional antagonism is necessary to induce fully efficacious lymphopenia by S1P1 receptor modulators, but there might be additional mechanisms in vivo that depend on efficient Gαi protein signaling. This was previously proposed to explain SEW2871- and S1P-induced lymphopenia (Jo et al., 2005). The requirement for potent and effective Gαi protein signaling has been also indirectly suggested by Xu et al. (2013), who analyzed the correlation between in vitro potency testing of S1P1 receptor modulators and peripheral lymphocyte count reduction. Interestingly, cAMP signaling, β-arrestin recruitment, and S1P1 receptor internalization were all found to be good predictors of in vivo lymphopenia, but inhibition of cAMP accumulation, which is caused by Gαi protein signaling, clearly showed the highest correlation (Xu et al., 2013). Similarly, BMS-986104, a S1P1 receptor modulator that is potent and fully efficacious in Gαi protein signaling, but which induces only partial receptor internalization, was recently reported to be fully efficacious in inhibiting lymphocyte egress in mice (Dhar et al., 2016).
A genetic mouse model, in which wild-type S1P1 receptors were replaced by internalization-deficient mutants (S5A-S1P1), was also used to dissect the effects of S1P1 receptor signaling and S1P1 internalization in the context of lymphocyte homing (Thangada et al., 2010). In this system, mice with T cells expressing mutant S5A-S1P1 receptors exhibited delayed onset lymphopenia upon FTY720 treatment and these mice were refractory to S1P lyase inhibition. Adoptive transfer experiments then demonstrated that the vascular compartment did not contribute to the observed pharmacology and that the effects of mutant S1P1 receptors were solely T cell driven. The genetic work shows that S1P1 receptor internalization rates influence lymphocyte egress kinetics and that mutant-induced changes in S1P1 receptor internalization alter lymphocyte egress kinetics in response to FTY720. Our findings using S1P1 receptor modulators with reduced Gαi protein signaling and lower receptor internalization rates are in agreement with these findings.
However, in contrast to the genetic model, where Gαi signaling was still fully maintained and FTY720 induced delayed lymphopenia, we now observe an almost complete loss of lymphopenia by using compound D3-2 that displayed the largest deficit in Gαi signaling compared with β-arrestin recruitment. This suggests that the apparent compound-intrinsic lack of potent Gαi protein signaling significantly impacts the ability to induce lymphopenia. This might indicate that lymphocyte egress kinetics are faster than compound-induced internalization, in agreement with the observed slow S1P1 receptor internalization in vitro and the notion that in vivo lymphopenia was observed to occur late, for example, for D3-2 only after 24 hours when plasma concentrations were already low. This would allow lymphocytes to exit secondary lymph nodes before a substantial amount of S1P1 receptor is internalized and made refractive from sensing the S1P gradient. However, repetitive administration over 3 days of compounds with attenuated Gαi protein signaling did not result in a bigger reduction of blood lymphocyte count. Alternatively, other cell types, such as endothelial cells, expressing S1P1 receptors could contribute in the exit process through S1P1 receptor-induced and Gαi-mediated processes. It is thus conceivable that different mechanisms such as S1P gradient obliteration, lymphatic endothelial barrier function increase, or modulation of T cell sensing of S1P gradients influence the lymphopenic response to S1P1 receptor modulators.
In summary, our study demonstrates that S1P1 receptor modulator-induced Gαi-mediated signaling and β-arrestin recruitment are both necessary to induce efficient and rapid lymphopenia in vivo. Future studies using these compounds as pharmacological tools, possibly in combination with additional genetic models, might help to elucidate the exact mechanism by which the synthetic S1P1 receptor modulators induce lymphopenia. Unraveling those mechanisms might facilitate the discovery of novel S1P1 receptor modulators with unique signaling properties to treat human disease.
Acknowledgments
The authors thank Giulia Ranieri for experimental support and Martine Clozel for stimulating discussions.
Authorship Contributions
Participated in research design: Birker-Robaczewska, Bolli, de Kanter, Kohl, Lescop, Steiner, Nayler.
Conducted experiments: Birker-Robaczewska, Poirey, Boucher, Rey.
Performed data analysis: Birker-Robaczewska, Bolli, de Kanter, Lescop, Steiner, Nayler.
Wrote or contributed to the writing of the manuscript: Birker-Robaczewska, Nayler.
Footnotes
- Received April 25, 2017.
- Accepted November 27, 2017.
All experiments were conducted at the research facilities of Actelion Pharmaceuticals Ltd. The authors acknowledge that the work was performed when they were employees of Actelion Pharmaceuticals Ltd. During manuscript review, Actelion Pharmaceuticals Ltd. was acquired by Johnson & Johnson, and its drug discovery and early development activities were subsequently transferred to the newly created company, Idorsia Pharmaceuticals Ltd., where the authors are currently employed.
↵This article has supplemental material available at molpharm.aspetjournals.org.
Abbreviations
- DMSO
- dimethylsulfoxide
- fafBSA
- fatty acid-free bovine serum albumin
- FTY720
- fingolimod
- Gαi
- G protein alpha i subunit
- HMVEC-LLy
- human lung lymphatic microvascular endothelial cells
- SEW2871
- 5-[4-phenyl-5-(trifluoromethyl)-2-thienyl]-3-[3-(trifluoromethyl)phenyl]-1,2,4-oxadiazole
- S1P
- sphingosine-1-phosphate
- Copyright © 2018 The Author(s).
This is an open access article distributed under the CC BY Attribution 4.0 International license.