Abstract
Clozapine, by virtue of its absence of extrapyramidal side effects and greater efficacy, revolutionized the treatment of schizophrenia, although the mechanisms underlying this exceptional activity remain controversial. Combining an unbiased cheminformatics and physical screening approach, we evaluated clozapine's activity at >2350 distinct molecular targets. Clozapine, and the closely related atypical antipsychotic drug olanzapine, interacted potently with a unique spectrum of molecular targets. This distinct pattern, which was not shared with the typical antipsychotic drug haloperidol, suggested that the serotonergic neuronal system was a key determinant of clozapine's actions. To test this hypothesis, we used pet1−/− mice, which are deficient in serotonergic presynaptic markers. We discovered that the antipsychotic-like properties of the atypical antipsychotic drugs clozapine and olanzapine were abolished in a pharmacological model that mimics NMDA-receptor hypofunction in pet1−/− mice, whereas haloperidol's efficacy was unaffected. These results show that clozapine's ability to normalize NMDA-receptor hypofunction, which is characteristic of schizophrenia, depends on an intact presynaptic serotonergic neuronal system.
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INTRODUCTION
Schizophrenia, a devastating illness affecting nearly 1% of the world's population, appears to be a genetically heterogeneous disorder with no single major risk allele (Purcell et al, 2009; Shi et al, 2009; Stefansson et al, 2009; Stefansson et al, 2008). This extreme genetic heterogeneity will make it difficult, if not impossible, to develop new medications that specifically target the presumably dysregulated pathways. Despite the polygenic nature of the illness, however, the symptoms of schizophrenia can be reduced, to various degrees of efficacy, by antipsychotic medications (Lieberman et al, 2005). Of the various medications currently available to treat schizophrenia, clozapine is uniquely effective (Kane et al, 1988). Indeed, clozapine—a drug discovered >50 years ago (Hippius, 1999)—has long been known to effectively treat schizophrenia without associated extrapyramidal symptoms (EPS) (Angst et al, 1971). Clozapine has also been demonstrated to be uniquely effective in reducing suicidality (Meltzer et al, 2003; Meltzer and Okayli, 1995). Clozapine has a number of serious side effects, including a nearly 1% risk of fatal agranulocytosis (Senn et al, 1977), limiting its use to treatment-resistant or treatment-intolerant patients. The discovery of clozapine's characteristic ability to treat schizophrenia without inducing EPS led to the development of the so-called ‘atypical’ antipsychotic drugs, which are now among the most widely prescribed neuropsychiatric medications (Lieberman et al, 2005).
For many years, it has been appreciated that clozapine and related atypical antipsychotics have extraordinarily robust pharmacological profiles, with potent interactions at a large number of mainly postsynaptically localized biogenic amine receptors, including several serotonin (Meltzer et al, 1989; Peroutka et al, 1981; Roth et al, 1992; Roth et al, 1994), dopamine (Creese et al, 1976; Van Tol et al, 1991), adrenergic (Enna et al, 1976), and muscarinic (Bolden et al, 1992; Miller and Hiley, 1974) G-protein-coupled receptors (GPCRs) (Roth et al, 2004). It is currently unknown, and the subject of considerable controversy, which, if any, of these pharmacological properties are essential for either the unique spectrum of efficacy or the unusual side-effect profile of clozapine. One aspect of their actions that has recently become clear, however, is the observation that only clozapine and the closely related atypical antipsychotic drugs are effective in genetic and pharmacological models that mimic the NMDA-receptor hypofunction of schizophrenia (Abbas et al, 2009; Bakshi et al, 1994; Belforte et al, 2010; Mohn et al, 1999) Without a clearer understanding of the molecular and neuronal substrates responsible for these actions, it will remain difficult, if not impossible, to develop new antipsychotic drugs with either improved efficacies or fewer side effects (Conn and Roth, 2008).
To discover the molecular and neuronal determinants of clozapine's actions, we utilized our unbiased chemical, biological, and cheminformatic approaches to deconstruct clozapine's molecular and cellular actions (Armbruster and Roth, 2005; Keiser et al, 2007; Keiser et al, 2009). We discovered that clozapine and the related atypical antipsychotic drug olanzapine, but not haloperidol, displayed a unique spectrum of activity at selected molecular targets. This pattern of activity suggested to us that the serotonin neuronal phenotype was an essential mediator of clozapine's actions. The ETS-domain transcription factor pet1 has recently emerged as a key determinant of the serotonergic phenotype (Hendricks et al, 1999; Hendricks et al, 2003; Jensen et al, 2008) of neurons, and pet1−/− mice almost completely lack the presynaptic component of the serotonergic phenotype, including tryptophan hydroxylase 2 (Tph2), the serotonin transporter (SERT), the vesicular monoamine transporter 2, and aromatic amino acid decorboxylase in dorsal raphe neurons of adult KO mice. These mice express only 20% of the adult level of 5-HT (Hendricks et al, 2003). We discovered that genetically induced deletion of the presynaptic component of the serotonergic neuronal system selectively abolished the ability of clozapine to normalize NMDA-receptor hypofunction in mouse pharmacological models of schizophrenia. Importantly, genetic deletion of the main postsynaptic receptor implicated in clozapine's actions (HTR2A) did not abolish clozapine's therapeutic actions. These results demonstrate an unexpectedly essential role for the presynaptic component of the serotonin neuronal system for clozapine's therapeutic actions.
MATERIALS AND METHODS
Mice
A detailed description of how the pet1−/− mice were generated is provided elsewhere (Hendricks et al, 2003). All experiments were approved by the institutional animal care and use committee at the University of North Carolina, Chapel Hill. Mice were housed under standard conditions—12 h light/dark cycle and food and water ad libitum.
Radioligand Binding Assays
For saturation binding assays, brain regions were rapidly microdissected, frozen on dry ice, and then stored at −80 °C. A Tissue TearorTM (BioSpec Products) was used to homogenize tissue (15 s, 15 000 r.p.m.) in ice-cold standard binding buffer (SBB—50 mM Tris-HCl, pH 7.4; 10 mM MgCl2; 0.1 mM EDTA). Homogenized tissue was centrifuged for 20 min at 27 000 g (4 °C); crude membrane pellets were collected and washed two more times in a total of 10 ml of SBB. After the last wash, the membrane pellet was either used immediately for binding, or stored at −80 °C until use. Saturation binding assays were performed with the homogenized brain tissue and [3H]-ketanserin (5-HT2A; cortex) or [3H]-WAY100635 (5-HT1A, cortex, midbrain, and hippocampus), and then incubated in SBB for 1.5 h as detailed (Abbas et al, 2009). Nonspecific binding was determined by incubating the reactions with 10 μM ritanserin (5-HT2A) or 10 μM buspirone (5-HT1A). Reactions were harvested by vacuum filtration through glass filters (3 × ice-cold 50 mM Tris, pH 7.4; pH 6.9 at room temperature) and measured by liquid scintillation using a Perkin-Elmer Tri-Carb 2800TR scintillation counter. Nonlinear saturation analysis was done using Graphpad Prism 4.01 to obtain Bmax values, and Bradford protein assays were performed in order to normalize Bmax determinations to the amount of protein in each assay.
Western Blotting
DOI (1-(4-iodo-2,5-dimethoxyphenyl)propan-2-amine hydrochloride) or vehicle was injected intraperitoneally (i.p.) with light restraint to minimize stress effects, and mice were killed 15 min later by cervical dislocation. Microdissection was performed on ice as quickly as possible. For detection of pERK1/2, tissue was homogenized in 300 μl of ice-cold SBB plus protease and phosphatase inhibitor cocktails (Roche Diagnostics, Complete, no. 11697498001; PhosSTOP, no. 04906845001) and 5% glycerol, and centrifuged for 10 min at 20–25 000 g and 4 °C. Then, 25–30 μg of protein from the supernatant was used to measure phospho- and total ERK1/2 using 10% SDS-PAGE followed by immunoblotting. The following antibodies were used for western blots in a 1 : 1000 dilution: rabbit polyclonal anti-p-ERK1/2 antibody (9101L, Cell Signaling), and rabbit polyclonal anti-ERK1/2 antibody (9102L, Cell Signaling). For 5-HT2A receptor immunoblotting, frontal cortex crude membrane preparations were resuspended in cold lysis buffer (50 mM Tris-Cl, pH 7.4; 150 mM NaCl, 10% glycerol, 1% NP-40, 0.5% Na-deoxycholate, 0.5% CHAPS, plus protease inhibitor cocktail (Roche Diagnostics) and incubated on ice for 1 h. Detergent-soluble proteins were collected after 20 min of centrifugation at 4 °C and 12 500 g, and 500 μg (1.0 mg/ml) of protein was incubated with 25–30 μl (packed volume) of wheat germ agglutinin (WGA)-conjugated agarose beads (Vector Technology) for a minimum of 2 h at 4 °C on a rotary mixer. After three washes with 500 μl of lysis buffer, WGA-bound proteins were eluted with 40 μl of 1 × SDS-sample buffer, and whole eluates were resolved by SDS-PAGE. Rabbit polyclonal anti-5-HT2A receptor antibody (Neuromics, Edina, MN) was used in a 1 : 500 dilution for 12 h at 4 °C for measurement of 5-HT2A receptor protein. We have previously verified the specificity of the anti-5-HT2A receptor antibody using 5-HT2A WT and KO mice cortex tissue by immunoblotting (Magalhaes et al, 2010)
Head-Twitch Response
As previously detailed (Abbas et al, 2009), mice were injected i.p. with 0.5–5.0 mg/kg of DOI. Head twitches were counted simultaneously by two observers (live, not on recordings), one of whom was blinded to the genotype, and recorded in 5-min bins for a total period of 30 min immediately after injection.
Whole-Cell Recording in CA1 Pyramidal and Dorsal Raphe Neurons
Adult pet1−/− and pet1+/+ littermate mice were decapitated, and their heads placed into a beaker containing ice-cold oxygenated artificial cerebrospinal fluid (aCSF: (in mM) sucrose 248, KCl 3.0, NaH2PO4 1.25, MgSO4 2.0, CaCl2 2.5, dextrose 10, and NaHCO3 26) for approximately 10 min. Following this, the brain was removed, 200 μm vibratome slices of the hippocampus or the midbrain were made and placed in a holding chamber in a water bath (36 °C) for 1 h, and then maintained at room temperature until used. Single slices were placed in a recording chamber (Warner Instruments, Hamden, CT), and continuously perfused with aCSF (NaCl 124 mM replaced sucrose) at 2 ml/min at 32 °C maintained by an in-line solution heater (SH-27B, Warner Instruments). Neurons were visualized using a Nikon E600 (Optical Apparatus, Ardmore, PA) upright microscope fitted with a × 60 water-immersion objective, differential interference contrast (DIC) optics, and an infrared filter (IR). Recording pipettes were fashioned on a P-97 micropipette puller (Sutter Instruments, Novato, CA) using borosilicate glass capillary tubing (1.2 mm OD, 0.69 mm ID; Warner Instruments). The electrolyte for recording cellular characteristics was (in mM): K gluconate 130, NaCl 5, MgCl2 1, Naphosphocreatinine 10, EGTA 0.02, HEPES 10, MgATP 2, Na2GTP 0.5, and 0.1% Biocytin, pH 7.3. A visualized pyramidal cell in the CA1 subfield of the dorsal hippocampus or a raphe neuron from the ventromedial subfield of the dorsal raphe was approached with the electrode, a giga Ω seal established, and the cell membrane ruptured to obtain a whole-cell recording using a multi-clamp 700B amplifier (Axon Instruments, Foster City, CA). Once the whole cell configuration was obtained, cell characteristics were recorded using current clamp techniques. The cellular characteristics were measured as previously described (Beck et al, 2004). Following the collection of cell characteristics, the pyramidal cell was returned to voltage clamp mode at −60 mV. After a stable baseline was established, 5-carboxyamidotryptamine (5-CT), a 5-HT1A agonist, to a final concentration of 100 nM was added to the aCSF, and the change in current was measured. Once a steady-state response was established, the drug was removed from the aCSF and only one cell was recorded per slice. The access resistance and the input resistance were continuously monitored throughout the recording period to assure quality of the recordings. Recordings were abandoned if the access resistance was more than four times the resistance of the electrode, or if the input resistance changed by >15%. For the dorsal raphe neurons, current clamp recordings were obtained of the hyperpolarization induced by activation of the 5-HT1A receptor by addition of 5-CT (100 nM) to the perfusion buffer. Unpaired t-tests were used to test for significance using the statistical package Prism.
Immunohistochemistry
Adult mice were anesthetized and transcardially perfused with 40 ml of phosphate-buffered saline (PBS), pH 7.4, followed by 4% paraformaldehyde (PFA) in PBS, pH 7.4. The brains were collected, postfixed overnight at 4 °C in 4% PFA, followed by dehydration in a 30% sucrose (w/v) solution in PBS overnight at 4 °C. Brain sections (30 μm coronal sections) were permeabilized for 1 h with 0.4% Triton X-100 in PBS, and were blocked for 2 h at room temperature in PBS containing 3% bovine serum albumin, 1% normal goat serum, and 0.4% Triton X-100. The slides were incubated with rabbit polyclonal anti-5-HT2A antibody (1 : 250, Neuromics) in blocking buffer for 48 h at 4 °C, followed by addition of anti-MAP2 mouse monoclonal antibody (1 : 5000, Sigma), and further incubated overnight at 4 °C. Slides were washed five times with PBS containing 0.4% Triton X-100; after that, goat anti-rabbit AlexaFluor-488 and goat anti-mouse AlexaFluor-594 antisera (1 : 250, Invitrogen, Eugene, OR) and Hoechst 3342 (0.5 μg/ml) were applied to slides for 1 h at room temperature. Fluorescent images were collected on a Nikon 80i Research Upright Microscope (Nikon, Tokyo, Japan) equipped with Surveyor Software with TurboScan (Objective Imaging, Kansasville, WI). Tiled images were collected with a Qimaging Retiga-EXi camera (Qimaging, Surrey, BC, Canada). Separate images were collected for the 5-HT2A receptor, nucleus (Hoechst), and MAP2 using either a × 10 or × 20 objective; these images were taken at 16-bit resolution (ie, 11 000 by 15 000 pixels). The relative distribution of the 5-HT2A receptor was quantified using ImageJ* software (NIH). Raw images were corrected by subtracting the average intensity value of the background. Twelve regions of interest (ROIs), 200 by 200 pixels, were randomly selected for layer V and peripheral layers, the mean intensity was then measured for each ROI, and these were averaged for each brain section. The Hoechst and MAP2 staining were used as reference images.
Brain slice immunohistochemistry for biocytin and tryptophan hydroxylase was conducted to determine whether the neurons recorded from the pet+/+ mice contained 5-HT as previously described (Beck et al, 2004). Slices from the pet1−/− mice were also processed to detect expression of the lacZ marker of 5-HT precursor neurons as previously described (Scott et al, 2005), but using chicken anti-β-galactosidase (1 : 1000, Abcam) and FITC-conjugated goat anti-chicken (1 : 250, Abcam) antibodies.
Prepulse Inhibition of Acoustic Startle
All prepulse inhibition (PPI) experiments were performed at the Mouse Behavioral Phenotyping Laboratory Core Facility in the Neurodevelopmental Disorders Research Center of UNC using the SR-Lab equipment (San Diego Instruments) as previously described (Abbas et al, 2009). Briefly, mice were placed in a small Plexiglas cylinder housed within a large sound-proofed chamber (San Diego Instruments). Each session consisted of a 5-min habituation period followed by 74 trials of 3 types—(1) no stimulation, (2) 120 dB acoustic stimulus (AS50), and (3) four different prepulse stimuli ranging from 4 dB over background (PP68) to 16 dB over background (PP78). PPI of acoustic startle was measured in the presence of a 64-dB white-noise background. Mice were given three different types of trials. One trial type consisted of a 40 ms 120 dB white-noise startle stimulus. In the second, the startle stimulus was preceded by a 20-ms prepulse stimulus that was 4, 8, 12, or 16 dB above the white-noise background. In the third trial type, no auditory startle stimulus was presented, but only prepulse stimuli were presented, and these null trials served as controls for background movements by the animals. During testing, mice were acclimated to the apparatus for 5 min and then given 74 test trials. In 30 of the trials, the 120 dB stimulus was given alone (startle-only trials), whereas eight additional trials served as null trials. For the remaining 36 trials, the prepulse stimulus preceded the startle stimulus by 100 ms. The behavioral responses were measured as the peak startle response for each trial between 35 and 65 ms after the onset of the startle stimulus. Inhibition of the startle response was calculated for each intensity of prepulse as the ratio of the prepulse trials to the startle-only trials subtracted from 1 and expressed as a percentage inhibition of response, that is, % PPI=[1–(prepulse trials/startle-only trials)]*100. For pharmacological studies, pet1−/− mice and WT littermates were injected i.p. 30 min before PPI testing with vehicle (saline), clozapine (0.5 or 1.0 mg/kg), and olanzapine (0.5 mg/kg).
Locomotor and Stereotypic Activity
Locomotor activity was assessed in photocell-based activity chambers under standardized environmental conditions, using an AccuScan activity monitor (AccuScan Instruments, Columbus, OH) with a 25.8 × 25.8 cm Plexiglas chamber and a beam spacing of 1.52 cm as described (Abbas et al, 2009). Mice were injected i.p. with vehicle, haloperidol (0.1 mg/kg), and clozapine (0.5 or 1.0 mg/kg) 30 min before PCP (7.0 mg/kg), followed by placement in the activity chambers. Activity data were collected for each mouse over 60 min, beginning when the mouse was first placed in the testing chamber. Horizontal activity was measured as the total distance covered in centimeters as the total of all vectored X-Y coordinate changes. Stereotypy data were also collected in this automated fashion and calculated by these software packages based on contiguous breaks of the same single beam or a set of beams. Data are presented as total stereotypy counts, that is, number of repetitive beam breaks during 60 min of activity monitoring.
Ligand Sets for SEA
We extracted ligand sets from databases that annotate molecules by therapeutic or biological category (Keiser et al, 2009). For instance, the 2006.1 MDL Drug Data Report (MDDR) contains 518 molecules annotated as α1 adrenergic receptor blockers, which we grouped into a single ‘α1 adrenergic blocker’ set. Three chemical databases provided these ligand sets: the ChEMBL 2009 (available from EMBL-EBI, http://www.ebi.ac.uk/chembldb), the World of Molecular Bioactivity (WOMBAT) 2006.2 (Olah et al, 2004; Oprea et al, 2007), and the MDDR 2006.1 (MDL, now provided by Symyx) databases. For the ChEMBL and WOMBAT data sets, we organized ligands by their affinities, representing each protein target by three sets at 1 and 10 μM cutoffs (as well as an additional 100 μM cutoff for WOMBAT).
Similarity Ensemble Approach (SEA)
Clozapine, olanzapine, and haloperidol were computationally screened via SEA against a panel of 3725 protein targets. Each target was represented solely by its set of known ligands. We used both the 1024-bit folded ECFP4 (Hert et al, 2008) and 2048-bit daylight (James et al, 1992) fingerprints for SEA, as separate screens, and accepted the highest-scoring predictions arising from either fingerprint. Because of the small size of the query data set (three drugs), all SEA predictions are reported here by P-values instead of by E-values (Keiser et al, 2009).
Estimates of Number of Targets Screened
We extracted 3725 targets for the cheminformatics screen from three databases: MDDR (246 targets), ChEMBL (2010 targets), and WOMBAT (1469 targets). However, there was appreciable target overlap across databases; we estimate that only 2250 of these targets are unique. To do so, we extracted accession numbers and UniProt IDs for each target and merged redundant targets via a synonym lookup table using UniProtKB/SwissProt and UniProtKB/TrEMBL database downloads (from http://www.uniprot.org, accessed 27 January 2010). We found 511 targets in common between ChEMBL and WOMBAT, leaving 1499 targets only found in ChEMBL and 536 targets only found in WOMBAT. Of the 536 WOMBAT-only targets, 296 did not have an accession number or UniProt ID; we excluded these from our counts to arrive at the lower-bounds estimate of 2250 unique cheminformatics targets. We determined by manual inspection that 162 of the 307 targets from the physical screen overlapped with the 2250-target cheminformatics screen. This yielded a final estimate of 2395 unique targets screened (Supplementary Table 3).
Kinase Profiling and Checkpoint Kinase 2 Assay
We profiled clozapine (10 μM) activity on a set of 20 different kinases using Caliper Profiler Pro kinase assays and Labchip EZ reader according to the manufacturer's instruction (Caliper Life Sciences, Hopkinton, MA). The CHK2 activity assay was carried out in opaque 96-well plates using Omnia Kinase Assay Kit (Invitrogen, KNZ1031). The assay was set up in triplicate in a final reaction volume of 20 μl per well containing 10 μM of peptide substrate, 1 mM DTT, and varying concentrations of test drug or water to measure maximal kinase activity. Thereafter, 18 mU of CHK2 enzyme protein (Invitrogen no. PV3367) was added to each well and the plate was loaded immediately into a FlexStation II reader (Molecular Diagnostics) at 30 °C, mixed for 5 s, and read (excitation at 360 nm and emission at 485 nm) every 30 s for the next 60 min. Plateau readings at the 30 min point were processed and analyzed to calculate IC50 of tested compounds using GraphPad Prism 5.0.
Statistical Analysis
For quantitation of immunoblots, comparison of Bmax data, and other two-group comparisons, two-tailed unpaired t-tests were used to ascertain statistical significance. All behavioral data were analyzed by two-way ANOVA followed by Bonferroni post tests for comparing multiple groups. Comparisons were considered significant if p-value was <0.05.
RESULTS
Clozapine Interacts with a Defined Subset of Molecular Targets
Because the molecular target(s) responsible for clozapine's actions remain controversial, we initially utilized an unbiased physical screening approach in which clozapine and selected typical and atypical antipsychotic drugs were profiled against all known molecular targets implicated in antipsychotic drug actions. The targets interrogated included both validated antipsychotic drug targets (eg, D2, D3 dopamine; 5-HT2A serotonin) as well as most of the currently investigated targets (eg, M1, M4 muscarinic; mGluR2/3 metabotropic glutamate; nicotinic acetylcholine) (Conn and Roth, 2008; Gray and Roth, 2007; Jensen et al, 2008). We then performed hierarchical clustering analysis to identify atypical antipsychotic drugs that were most similar to clozapine and typical antipsychotic drugs that were most dissimilar. As shown in Figure 1a, olanzapine was the most similar atypical antipsychotic drug to clozapine, whereas haloperidol was the most dissimilar typical antipsychotic drug. We then chose clozapine, olanzapine, and haloperidol for further study.
The ‘druggable genome,’ of which the receptorome (Armbruster and Roth, 2005), the kinome (Manning et al, 2002), enzymes, and other ‘druggable’ targets (Hopkins and Groom, 2002) are part, is estimated to represent perhaps 2300 distinct molecular targets (Hopkins and Groom, 2002). Although it is not currently technically feasible to obtain the activity profile of clozapine at every conceivable druggable target, we have been able to achieve satisfactory coverage of these druggable targets falling into the GPCR, kinase, transporter, ion channel, and enzyme classes. To investigate whether there might be other likely targets, not available among these readily screenable targets, we used our newly validated computational SEA (Keiser et al, 2007; Keiser et al, 2009) to screen all three drugs against a panel of ∼2250 molecular targets, all of which have annotated ligands. These calculations also allowed us to investigate the similarities and differences in target association among the three drugs; we were particularly interested to see whether clozapine and olanzapine associated with similar targets, and whether these differed substantially from the targets with which SEA predicted haloperidol to associate (Supplementary Table 1). SEA predicted only one new target for clozapine, farnesyl protein transferase (PFTase, Supplementary Table 1). The SEA predictions suggested new targets for olanzapine, such as the 5-HT3A serotonin receptor (HTR3A; likelihood of random association, P-value, 1.09 × 10−10), the 5-HT3B serotonin receptor (HatAR3B; P-value 1.18 × 10−8), the H4 histamine receptor (HRH4; P-value 3.69 × 10−8), and UDP-glucuronosyltransferase 1A4 (UGT1A4, P-value 1.63 × 10−18; Supplementary Table 1). In each of these cases, the olanzapine-predicted target is a known target of clozapine that is neither predicted for nor known to interact with haloperidol. However, upon inspection, each of these targets is already reported to be a target for olanzapine in KiDB, whereas UGT1A4 is known to directly glucuronidate olanzapine (Linnet, 2002). Except for PFTase (P-value 2.46 × 10−5), none of the predicted targets differs greatly from those that both drugs were already known to modulate.
We next physically interrogated a large portion of the druggable genome to determine if there could be additional targets for clozapine that were not predicted by SEA. Figure 1b shows the combined results obtained from our queries of internally derived physical screening campaigns from the NIMH-PDSP as well as the publicly available physical screening campaigns extracted from the PubChem database (see Supplementary Table 2 for the complete data set) at >300 target-based assays. As shown in Figure 1b and Supplementary Table 2, clozapine and olanzapine differed from haloperidol by virtue of their high-affinity interactions with most of the 14 human serotonin GPCRs and relatively lower affinity interactions with D2, D3, and D4 dopamine receptors. Furthermore, Figure 2a shows the lack of activity of clozapine at various protein kinases implicated in psychotherapeutic drug actions (eg, GSK3β, Erk1, Erk2, and Akt1) (Beaulieu et al, 2009; Beaulieu et al, 2008; Beaulieu et al, 2005). In passing, we note that clozapine was a moderately potent inhibitor of CHK2 (Figure 2b)—a kinase involved in cell cycle regulation (Matsuoka et al, 1998).
The Presynaptic Component of Serotonin Neurons Is Essential for Clozapine's Ability to Normalize the NMDA-Receptor Hypofunction Characteristic of Schizophrenia
The results of Figure 1 suggested to us that the most likely locus of clozapine's actions was engagement of the serotonergic neuronal system. Because many serotonin receptors are both pre- and post-synaptic with respect to serotonin neurons, it was not clear whether the requirement for serotonergic engagement would be pre- or post-synaptic, although current hypotheses posit a selective effect of clozapine on postsynaptic serotonin receptors (eg, HTR2A, HTR2C, HTR6, and HTR7; Conn and Roth, 2008; Roth et al, 2004). These hypotheses predict that deletion of the presynaptic component of the serotonin neuronal system would not affect clozapine's therapeutic actions. To test these hypotheses, we took advantage of the observation that the ETS-domain transcription factor pet1 is essential for normal expression of the serotonergic phenotype in neurons, and that its deletion greatly diminishes expression of presynaptic serotonergic markers (Hendricks et al, 2003; Jensen et al, 2008; Scott et al, 2005).
For initial studies, we examined the ability of clozapine to normalize the disruption of PPI induced by the noncompetitive NMDA-receptor antagonist phencyclidine (PCP). We chose PCP because it is known to induce a psychotic state that reliably mimics both the positive and negative symptoms of schizophrenia in humans (Javitt and Zukin, 1991). Disrupted PPI is also well established and validated as a measure of the impaired sensory-motor gating characteristic of schizophrenia (Geyer and Braff, 1987; Mansbach and Geyer, 1989). Importantly, atypical antipsychotic drugs like clozapine are unique in their ability to normalize PCP-induced disruption of PPI (Bakshi et al, 1994). As is shown in Figure 3a, acute administration of PCP induced a marked disruption of PPI in both pet1−/− and pet1+/+ littermate control mice. Significantly, clozapine normalized PCP-disrupted PPI in pet1+/+ but not in pet1−/− mice (Figure 3a). To determine if these results were unique to clozapine, we tested olanzapine as well, because it most closely mimics the polypharmacological profile of clozapine. As shown in Figure 3b, olanzapine normalized PCP-disrupted PPI in pet1+/+ but not in pet1−/− mice. These results indicate that genetic deletion of pet1 abolishes the ability of both clozapine and olanzapine to normalize NMDA-receptor hypofunctioning. Therefore, the actions of clozapine and olanzapine depend on the presynaptic component of the serotonergic neuronal system. We also examined the ability of clozapine to normalize the PCP-induced enhancement of locomotor activity and stereotypy. As shown in Figures 3c and d and 4, PCP induced a significant enhancement of locomotor behavior and stereotypical movements, which were normalized by clozapine in pet1+/+ (Figure 3c) but not in pet1−/− (Figure 3d) mice. As an essential control, we show that the typical antipsychotic haloperidol normalized locomotor behavior and stereotypy in both pet1+/+ and pet1−/− mice (Figures 3e, f and 4a)—a result predicted based on its relatively selectively potent interaction with D2-family dopamine receptors, in contrast to the profiles of clozapine or olanzapine, which more preferentially target 5-HT receptors.
Given these results, we wondered if genetic deletion of 5-HT2A serotonin receptors, which have been proposed to mediate many of clozapine's unique actions (Meltzer et al, 1989), might phenocopy pet1 deletion, at least with respect to clozapine's antipsychotic-like actions. Accordingly, we examined the ability of clozapine to normalize PCP-induced disruption of PPI in 5-HT2A+/+ and 5-HT2A−/− mice. As shown in Figure 4b, clozapine normalized PCP-induced PPI disruption in both 5-HT2A−/− and WT littermate control mice. We also noted that 5-HT2A+/+ and 5-HT2A−/− mice were generated on the 129S background strain and displayed a diminished sensitivity to clozapine. We performed dose response with clozapine (data not presented) in these mice, and the data with the lowest effective doses of clozapine in 5-HT2A−/− and WT littermates are shown in Figure 4b. These results indicate that postsynaptic 5-HT2A receptors are not essential for mediating clozapine's ability to normalize PCP-induced disruption of sensory-motor gating in vivo.
Given these results, we wondered if one possible explanation for the inability of clozapine to normalize behavioral measures of NMDA-receptor hypofunction could be that genetic disruption of pet1 has altered the cellular expression and/or sensitivity of postsynaptic 5-HT2A serotonin receptors. To address this possibility, we measured cortical 5-HT2A receptor protein levels via western blot, 3H-ketanserin radioligand binding, and immunofluorescence analysis. We found equivalent amounts of 5-HT2A receptor protein, radioligand binding (Figure 5a–c), and a similar cellular and subcellular distribution of 5-HT2A receptors in pet1+/+ and pet1−/− mice (Figure 5d and e). To determine if a change in postsynaptic 5-HT2A receptor sensitivity was present in pet1−/− mice, we evaluated DOI-induced head-twitch and pERK responses in pet1+/+ and pet1−/− mice, as previously described (Abbas et al, 2009). As can be seen in Figure 5f–h, DOI-induced responses were augmented in pet1−/− mice, as might be expected given the loss of presynaptic 5-HT innervations seen in pet1−/− mice. We also determined the 5-HT2C expression level in hippocampus, as clozapine has affinity for this receptor, and found significantly increased 5-HT2C expression in hippocampus of pet1−/− mice in comparison with WT littermate controls (Supplementary Figure 1). Furthermore, the antipsychotic-like properties of M100907 (5-HT2A selective antagonist) and MK212 (5-HT2C selective agonist) for normalizing the PCP-induced disruption of PPI is selectively blunted in pet1−/− mice (Supplementary Figures 2 and 3). These results indicate that the inability of atypical antipsychotic drugs to normalize NMDA-receptor hypofunction in pet1−/− mice is not because of 5-HT2A or 5-HT2C postsynaptic receptor insensitivity.
It has also been suggested that clozapine-like drugs exert their effects principally via direct (or indirect) activation of 5-HT1A serotonin receptors (Newman-Tancredi et al, 1998; Rollema et al, 1997). It is conceivable, therefore, that a diminution of 5-HT1A receptor number and/or sensitivity could exist in mice with a genetic deletion of pet1. To address this possibility, we quantified cortical 5-HT1A receptors via 3H-WAY100635 radioligand binding and found that pet1−/− mice showed more (not less) 3H-WAY100635 binding than pet1+/+ mice in the cortex and hippocampus (Figure 6a). We also examined the electrophysiological properties of 5-HT1A receptors in hippocampal slices from pet1+/+ and pet1−/− mice and found, as would be expected from the binding data, a significantly exaggerated response in pet1−/− when compared with pet+/+ mice (Figure 6b and c). Taken together, these results indicate that clozapine's inability to rescue NMDA-receptor hypofunctioning is not because of diminished forebrain 5-HT1A receptor expression or activity.
Finally, and most critically, we interrogated the physiological function of the presynaptic component of the serotonin neuronal system to verify its relative ablation in pet1−/− mice. We first utilized the psychotomimetic agent methylene-dioxy-methamphetamine (MDMA) that induces locomotion via a presynaptic release of 5-HT. As shown in Figure 7a and b, the locomotor effects of MDMA were abolished in pet1−/− mice. We next tested the presynaptic 5-HT1A receptor-mediated response electrophysiologically in midbrain raphe slices from pet1+/+ and pet1−/− mice. The magnitude of the 5-HT1A hyperpolarization recorded from the pet1 knockout mice was significantly less, and 14 out of the 24 neurons recorded demonstrated no response at all, as shown in Figure 7c and d. In contrast, the responses recorded from the pet1 wild-type mice were normal in magnitude (Figure 7c and d). These results confirm a functional ablation of the presynaptic component of the serotonergic neuronal system in pet1−/− mice. Taken together, these results demonstrate that an intact presynaptic component of the 5-HT neuronal system is essential for clozapine's actions.
DISCUSSION
In this paper, we identify the presynaptic component of the serotonin neuronal system as an essential mediator of atypical antipsychotic drug action in vivo. Although literally thousands of studies have been published regarding clozapine's actions, the molecular substrates essential for its unique effects remain intensely controversial. Indeed, previous studies have demonstrated that clozapine and related atypical antipsychotic drugs have preferentially high affinity for postsynaptic 5-HT2A serotonin (Meltzer et al, 1989), D4 dopamine (Van Tol et al, 1991), muscarinic acetylcholine (Miller and Hiley, 1974), as well as dozens of other GPCRs (Roth et al, 2004). Indeed, each of these individual molecular targets to which clozapine binds with high affinity has been subsequently exploited for drug discovery purposes. Drugs that have been developed that attempt to mimic clozapine's actions by selectively targeting these ‘clozapine receptors’ have all failed to be approved as efficacious treatments of schizophrenia. This spectacular drug discovery failure prompted us to re-examine the molecular and neuronal substrates responsible for clozapine's actions in vivo.
To comprehensively and in an unbiased fashion identify all the potential site(s) of action of clozapine, we initially screened a representative sample of known typical and atypical antipsychotic drugs against a panel of known molecular targets implicated in antipsychotic drug actions. Hierarchical clustering revealed that clozapine and olanzapine were most similar to each other among approved atypical antipsychotic drugs, and were very distinct from haloperidol. We then evaluated these three drugs against >300 distinct molecular targets to gain satisfactory physical screening coverage of the ‘druggable genome’ (Hopkins and Groom, 2002). We discovered that clozapine and olanzapine differed from haloperidol mainly by virtue of high affinities for nearly all known 5-HT receptors. In passing, we noted that clozapine and olanzapine were weak inhibitors of Chk2—a checkpoint kinase—although the potencies of clozapine and olanzapine for Chk2 (∼10 μM) are probably too low to be of therapeutic relevance. One unique class of druggable targets represented in our screen are the orphan GPCRs. Despite screening 26 of these orphans, we have failed to identify unique clozapine targets among them (data not shown). Efforts are ongoing to screen all 160+ orphan GPCRs as potential clozapine targets (WK Kroeze and BL Roth, unpublished).
To cast an even wider net, we also employed a new and unbiased computational method, the SEA, to identify possible targets for these three drugs beyond the panel of targets explicitly screened (Keiser et al, 2007; Keiser et al, 2009). SEA predictions predominantly recapitulated the known targets of these drugs, and even where new and previously uncharacterized targets were suggested for olanzapine, these had already been characterized for clozapine. Indeed, clozapine and olanzapine often shared predicted targets by SEA—primarily aminergic GPCRs—with which haloperidol was not predicted to associate. Combining the 307 targets interrogated from the physical screening campaign and the 2250 targets from the SEA screen, we have interrogated over 2350 targets by a combination of these two methods. Taken together, these results indicate that the three drugs evaluated interact mainly with known biogenic amine receptors, and that the probability is low that any additional druggable targets exist that could account for the unique actions of clozapine.
Given the preferentially high affinity of clozapine and olanzapine for most known 5-HT receptors, we postulated that the serotonergic neuronal system is required for clozapine's action. Indeed, for decades, it has been suggested, without confirmatory studies using knockout mice, that 5-HT and its receptors are key mediators of clozapine's actions (Fink et al, 1984; Carlsson et al, 1999). Here, we took advantage of the observation that genetic deletion of pet1 results in a generalized loss of 5-HT and the presynaptic component of the serotonin neuronal system (Hendricks et al, 2003). This diminution of brain serotonin led to an enhancement in 5-HT2A, 5-HT2C, and 5-HT1A responses. However, despite this apparent postsynaptic supersensitivity, we found that deletion of pet1 abolished clozapine's efficacy. Importantly, we also found that genetic deletion of 5-HT2A receptors—heretofore considered the main target implicated in clozapine's actions—only marginally attenuated clozapine's antipsychotic-like actions. Instead, these present findings implicate the presynaptic component of the 5-HT neuronal system as being essential for clozapine's unique actions.
Implications of These Findings for Psychiatric Drug Discovery
Although there is little debate regarding clozapine's unique efficacy in treating schizophrenia, the molecular and neuronal determinant(s) of clozapine's actions remain highly controversial. Some groups have proposed that clozapine is uniquely efficacious because of a combination of relatively low D2 receptor affinity (and associated fast dissociation rate) and/or high D4 dopamine receptor affinity (Kapur and Seeman, 2001; Seeman et al, 1997). This approach has led to the successful development of drugs like amisulpride that are relatively selective D2/D3 dopamine receptor antagonists (Schoemaker et al, 1997).
Others have suggested that clozapine via its principal metabolite N-desmethylclozapine potentiates NMDA-receptor function by virtue of M1 muscarinic receptor agonism (Sur et al, 2003; Wittmann et al, 2005). This hypothesis has led to a new crop of muscarinic subtype-selective allosteric potentiators currently being developed (Conn and Roth, 2008; Gray and Roth, 2007). Furthermore, it has also been shown that clozapine can potentiate NMDA activity by directly binding to glycine B site (Bressan et al, 2005; Javitt et al, 2005; Schwieler et al, 2008), thus contributing to its unique clinical efficacy. Clearly, however, the PCP-induced PPI disruption and hyperlocomoter response in mice do not model all aspects of schizophrenia and, therefore, other potential actions of clozapine were not addressed here.
Others, most prominently Meltzer and colleagues (Nash et al, 1988), who discovered that clozapine and related atypical antipsychotic drugs were characterized by relatively higher affinities for postsynaptic 5-HT2A serotonin receptors (HTR2A) when compared with D2 receptors, suggested that a balanced antagonism of 5-HT2A/D2 was required. This hypothesis led to the successful development of many currently prescribed atypical antipsychotic drugs, although none of them recapitulates the unique efficacy of clozapine (Lieberman et al, 2005). Meltzer and colleagues (Li et al, 2009) have also reported a requirement for cortical postsynaptic 5-HT1A receptors in mediating certain actions of clozapine and related atypical antipsychotic drugs. Based on the relatively high affinity of clozapine for various 5-HT receptors, a number of attempts have been made to develop clozapine-like atypical antipsychotic drugs that function as inverse agonists for various postsynaptic 5-HT2A, 5-HT2C, 5-HT6, and 5-HT7 receptors (Gray and Roth, 2007), although, to date, these efforts have not yielded approved atypical antipsychotic drugs.
Many other molecular target-based approaches for developing atypical antipsychotic drugs are currently underway. These include targeting various components of the glutamate synapse (eg, mGluR2/3 allosteric potentiators, mGluR5 potentiators, GlyT1 glycine transporter inhibitors, and AMPA receptor potentiators), nicotinic acetylcholine subtype-selective agents, phosphodiesterase 10A inhibitors, NK3-neurokinin receptor antagonists, and others (Conn and Roth, 2008; Gray and Roth, 2007; Karam et al, 2010). At present, it is unknown which, if any, of the above mechanistically designed (or single-target-based) approaches to treat schizophrenia require an intact presynaptic serotonergic neuronal system, although we are actively engaged in evaluating many of these drugs in pet1−/− mice (PN Yadav et al, unpublished).
By way of contrast, our results indicate that the presynaptic component of the serotonin neuronal system is a key determinant of clozapine's antipsychotic-like actions in mice in vivo. Therefore, a key feature for new antipsychotics would be a requirement for activity at the presynaptic component of the serotonergic neuronal system while simultaneously targeting various postsynaptic receptors to yield maximum efficacy. Clearly, designing such drugs with a focused serotonergic action, while minimizing side effects, will be the challenge for the next revolution in treating schizophrenia.
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Acknowledgements
This study was supported by U19MH82441, RO1MH61887, RO1MH075047, the NIMH Psychoactive Drug Screening Program Contract, and the Michael Hooker Distinguished Professorship to BLR. Additional support was from GM71896 (to JJI and BKS) MH075047 to SGB, MH082611 to LKC and the Rogers Family Foundation (to MJK, JJI, and BKS). BKS thanks Tudor Oprea for a gift of the WOMBAT database and John Overington for early access to ChEMBL.
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Dr Roth in the past 24 months has been a consultant for Bristol Myers Squibb, Otsuka Pharmaceuticals, Merck, Medivation, Galenea Pharmaceuticals, the National Institutes of Health, Invitrogen, and Albany Molecular Researech, and has received royalty payments from licensing of 5-HT receptor patents (which are owned by UNC and Case Western Reserve University) to Galena Pharmaceuticals. Drs Shoichet and Irwin are co-founders of SeaChange, and Dr Keiser is an employee of SeaChange. The other authors declare no conflict of interest.
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Yadav, P., Abbas, A., Farrell, M. et al. The Presynaptic Component of the Serotonergic System is Required for Clozapine's Efficacy. Neuropsychopharmacol 36, 638–651 (2011). https://doi.org/10.1038/npp.2010.195
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DOI: https://doi.org/10.1038/npp.2010.195