Key Points
-
The therapeutic modulation of several actions of the biogenic amine histamine has proved to be medically effective and also financially profitable. Antagonists that target the histamine H1 receptor (H1R) or the H2 receptor, which are used in the treatment of allergic conditions and gastric-acid-related disorders, respectively, have been 'blockbuster' drugs for many years.
-
Following the Human Genome Project, the family of histamine receptors has been extended to include four different G-protein-coupled receptors (GPCRs): the H1, H2, H3 and H4 receptors, and current expectations for the therapeutic potential of drugs that target the H3 and/or H4 receptor are high.
-
The identification of the H3 receptor at the molecular level in 1999 has greatly facilitated drug discovery efforts to target the H3 receptor, and currently many pharmaceutical companies are active in this field.
-
As reviewed in this article, many potent and relatively selective H3 receptor agonists and inverse agonists have now been developed. For both H3 receptor agonists and H3 receptor inverse agonists/antagonists, interesting activities in several preclinical models of important human diseases, including obesity, migraine, attention-deficit hyperactivity disorder, and inflammatory diseases, have been reported.
Abstract
Since the cloning of the histamine H3 receptor cDNA in 1999 by Lovenberg and co-workers, this histamine receptor has gained the interest of many pharmaceutical companies as a potential drug target for the treatment of various important disorders, including obesity, attention-deficit hyperactivity disorder, Alzheimer's disease, schizophrenia, as well as for myocardial ischaemia, migraine and inflammatory diseases. Here, we discuss relevant information on this target protein and describe the development of various H3 receptor agonists and antagonists, and their effects in preclinical animal models.
Similar content being viewed by others
Main
The therapeutic modulation of several actions of the biogenic amine histamine has proved to be medically effective and also financially profitable for the pharmaceutical industry. Antagonists that target the histamine H1 receptor or the H2 receptor, which are used in the treatment of allergic conditions such as allergic rhinitis and gastric-acid-related disorders, respectively, have been 'blockbuster' drugs for many years1. Recently, following the completion of the Human Genome Project, the family of histamine receptors has been extended to include four different G-protein-coupled receptors (GPCRs): the H1, H2, H3 and H4 receptors2. In view of the blockbuster status of the histamine H1 and H2 receptor antagonists, current expectations for the therapeutic potential of drugs that target the H3 and/or H4 receptor are high.
The H3 receptor was identified pharmacologically in 1983 by Arrang et al. and acts as a presynaptic autoreceptor that inhibits histamine release from histaminergic neurons in the rat brain3. Panula and Haas recently reviewed the role of histamine neurotransmission in the central nervous system (CNS)4. Histaminergic neurons are localized in the tuberomammillary nucleus of the hypothalamus, project to all major areas of the brain and are involved in many functions, including the regulation of sleep/wakefulness, feeding and memory processes4. Although the H3 receptor can also be found in the periphery (mainly, but not exclusively, on neurons), the CNS contains the great majority of H3 receptors (Refs 5–7). In rodents, H3 receptor expression is observed in, for example, the cerebral cortex, hippocampal formation, amygdala, nucleus accumbens, globus pallidus, striatum and hypothalamus by autoradiography8, immunohistochemistry9 or in situ hybridization5,6.
H3 receptor expression is not confined to histaminergic neurons, and, as a heteroreceptor, the H3 receptor is known to modulate various neurotransmitter systems in the brain. In rodent and/or human brains, H3 receptor activation inhibits presynaptically the release of many important neurotransmitters10. Despite this interesting feature, drugs that target the H3 receptor have until 1999 been mainly developed by academic research groups. The identification of the H3 receptor at the molecular level5 has greatly facilitated drug discovery efforts to target the H3 receptor and many pharmaceutical companies are currently active in this field.
Molecular biology of the H 3 receptor gene
The molecular architecture of the H3 receptor was unknown until Lovenberg et al. showed in 1999 that, like the H1 and H2 receptors11,12, the H3 receptor belongs to the large super-family of GPCRs5. A potential GPCR-related expressed sequence tag (EST) sequence with homology to α2 receptors was identified in silico in a search for orphan GPCRs and used to clone a full-length cDNA from a human thalamus cDNA library. The H3 receptor cDNA contains an open reading frame of 445 amino acids with all the features of a GPCR for a small biogenic amine5. The H3 receptor protein shows very low sequence similarity with other GPCRs. Overall similarity between the H3 receptor and the H1 and H2 receptors amounts to only 22% and 20%, respectively. This remarkable divergence explains why the H3 receptor gene was not cloned by similarity screening with H1- or H2-receptor-specific probes.
Efforts to discover novel GPCRs through similarity searching of genomic databases resulted in the rapid identification of an additional member of the histamine receptor family, the H4 receptor (Refs 13–18). Although the H4 receptor shows little overall sequence similarity to any of the other histamine receptors cloned so far, it has a similarity of ∼60% to the H3 receptor within the transmembrane domains. Owing to this considerable similarity between the H3 and H4 receptors, the H4 receptor pharmacology resembles, to some extent, the H3 receptor profile. Known H3 receptor ligands, including R-(α)-methylhistamine, immepip, imetit and clobenpropit, also act at the H4 receptor (see below), albeit with a different rank order of affinity and potency2.
It is now apparent that there is a large variety of H3 receptor isoforms that might have different pharmacological profiles (see Ref. 19 for a review). The H3 receptor isoforms differ in four regions of the receptor protein (Box 1, Table 1), and the number of possible H3 receptor isoforms is high owing to the simultaneous occurrence of multiple splicing events in the same H3 receptor mRNA molecule. So far, at least 20 different isoforms have been described on the basis of detection of varying H3 receptor mRNAs (Box 1). Human H3 receptor mRNA20, including mRNAs for various human H3 receptor isoforms, has been detected in the brain by means of reverse transcriptase-PCR (RT-PCR) (see also Refs 19,21,22). As the mRNAs for the H3 receptor isoforms other than the H3 (445) receptor isoform are not consistently detected by all investigators19,21,22,23, the exact expression patterns of the various H3 receptor isoforms remains elusive at this time. However, the overall picture suggests regional differences in the expression of the various H3 receptor isoforms. Although most observations have been made on the basis of the detection of H3 receptor mRNA, the proteins of some H3 receptor isoforms have also been detected in mouse and rat brains using H3 receptor isoform-specific antibodies9,24. The use of H3 receptor isoform-specific antibodies now provides clear biochemical evidence for the existence of multiple H3 receptor isoforms.
The H3 receptor445 isoform described by Lovenberg et al.5 is currently the best characterized H3 receptor isoform. Most isoforms differ from the H3 receptor445 isoform by large deletions of one or more stretches of amino acids (Box 1). Among these, the H3 receptor isoforms that have deletions in the third intracellular loop have received special interest, owing to the involvement of this receptor domain in G-protein coupling6. These H3 receptor isoforms, in particular, show different pharmacological profiles19, including agonist potencies21, signalling properties6 and constitutive activity25.
In addition to the H3 receptor isoforms, there is evidence for genetic polymorphism within the human H3 receptor. The amino acid at position 19 is reported to be either glutamic acid26 or aspartic acid5. A second polymorphism, resulting from an alanine to valine substitution at amino acid 280 (A280V) has been found in a patient with Shy–Drager syndrome (also known as neurological orthostatic hypotension), a disease that is characterized by neuronal degeneration and autonomic failure19,20. The H3 receptor A280V polymorphism might be related to the aetiology of the Shy-Drager syndrome through alterations in the release of noradrenaline as a result of the polymorphism. A third human H3 receptor polymorphism, resulting from a tyrosine to a cysteine substitution at amino acid 197 (Y197C), has recently been identified19. At present, no information is available on the potential functional differences between the various polymorphic variants.
Soon after the cloning of the human H3 receptor (Refs 5,27), the receptor was cloned by sequence similarity from various other species, including rats6,28,29,30, guinea-pigs31,32, mice33 and monkeys34. Although the H3 receptor sequence is highly conserved across these species (>90%), the H3 receptor showed considerable species differences19,26,28,30,34,35, with the human H3 receptor445 having the highest affinity for histamine, but lower affinity for some antagonists (for example, thioperamide and ciproxifan). In addition to the identification of species homologues of the H3 receptor gene, it seems that H3 receptor isoforms are not limited to humans14,20,21,22,36, but are also present in various species, including rats, guinea-pigs and mice6,25,29,31,37. However, the generation of H3 receptor splice variants seems to be highly species-specific34, complicating the evaluation of the various isoforms in relation to the effectiveness of H3 receptor ligands in vivo. The various rodent H3 receptor isoforms show differential brain expression6,22,29,31 and signalling properties6,22.
Following the cloning of the H3 receptor, H3 receptor knockout mice (H3−/−) were generated independently by two separate laboratories38,39. The available data from the H3 receptor−/− mice have recently been extensively reviewed by Chazot and Shenton40. In general, these data confirm previous pharmacological studies with H3 receptor ligands. Nevertheless, some unexpected results were observed with respect to arousal and food intake of the H3 receptor−/− mice40. So far, conditional H3 receptor−/− mice have not been available, and possible compensatory mechanisms have been put forward to explain the apparent anomalies40.
The H 3 receptor signals through G i/o proteins
The involvement of Gi/o proteins in H3 receptor signalling in the brain was originally shown by the pertussis toxin sensitivity of H3 receptor-agonist-dependent [35S]GTPγS binding in the rat brain41. The H3 receptor-mediated activation of Gi/o proteins has been confirmed through heterologous expression of the H3 receptor (Ref. 5). In various transfected cell lines, the H3 receptor is negatively coupled to adenylyl cyclase5 (Fig. 1). Adenylyl cyclase stimulates the formation of cyclic AMP (cAMP), which in turn activates protein kinase A (PKA) and subsequently cAMP-responsive-element-binding protein (CREB) to modulate gene transcription. As a result, H3 receptor activation lowers cAMP levels and reduces downstream events, such as CREB-dependent gene transcription5. Furthermore, H3 receptor activation of Gi/o proteins might result in the activation of other effector pathways (Fig. 1), including mitogen-activated protein kinase (MAPK)6,42 and phosphatidylinositol 3-kinase (PI3K) pathways. H3 receptor activation of Gi/o proteins might also lead to the activation of phospholipase A2 (PLA2) to induce the release of arachidonic acid43, the inhibition of the Na+/H+ exchanger44 and lowering of intracellular Ca2+ levels by a mechanism that might involve the impaired entrance of Ca2+ through voltage-gated ion channels45,46. Activation of the MAPK and PI3K pathways results in the phosphorylation of extracellular signal-regulated kinases (ERKs) and protein kinase B (PKB, also known as Akt), respectively47. Activated PKB will subsequently phosphorylate and thereby inhibit the action of glycogen synthase kinase 3β (GSK3β)47, a major tau kinase in the brain48. Interestingly, rat H3 receptor isoforms with deletions in the third intracellular loop differ in their effectiveness to activate cAMP-responsive element (CRE)-dependent transcription or MAPK activation6.
Although activation of the MAPK pathway by the H3 receptor, as well as the PI3K signalling pathway49, is involved in memory consolidation42, the lowering of intracellular levels of cAMP through the activation of H3 autoreceptors results in the modulation of histamine synthesis in histaminergic nerve terminals through the adenylate cyclase–PKA pathway50. The role of the activation of PKB/GSK3β by the H3 receptor in the brain is currently less clear, but dysregulation of GSK3 is linked to several prevalent pathological conditions, such as diabetes and/or insulin resistance, and Alzheimer's disease (AD)51.
Besides agonist-induced signalling, the H3 receptor is known to signal in an agonist-independent manner (Box 2). In fact, the H3 receptor is one of the few examples for which constitutive GPCR signalling has been shown to occur in vivo.
Histamine H 3 receptor agonists
The structural diversity among histamine H3 receptor agonists is limited. The endogenous agonist histamine (compound 1) binds with high affinity to the human H3 receptor. So far, all H3 receptor agonists closely resemble histamine and contain a 4(5)-substituted imidazole moiety (Fig. 2). Efforts to replace this heterocyclic moiety have so far been unsuccessful52,53. Furthermore, additional substituents attached to the 4(5)-substituted imidazole ring eliminate H3 receptor activity52. By contrast, small structural modifications of the imidazole side chain of histamine can result in very potent and selective H3 receptor agonists. Methylation of the basic amine group gives Nα-methylhistamine (compound 2), a H3 receptor agonist that is about three times more active than histamine54. The tritiated analogue of compound 2 can be readily obtained and is frequently used for H3 receptor-binding studies. Methylation of the imidazole side chain has resulted in the identification of (R)-α-methylhistamine (RAMH (compound 3); pKi = 8.4, human H3 receptor)55, which can be considered as the archetypal H3 receptor agonist. Together with its less active (S)-isomer, the eutomer RAMH has been used in many pharmacological studies, but its use under in vivo conditions is limited because of its high basicity and hydrophilicity, extensive metabolism (especially as a substrate of hepatic human histamine amino (N)-methyltransferase) and low bioavailability. These problems were overcome by the research group of Schunack by applying an azomethine PRODRUG concept to RAMH, resulting in BP 2-94 (compound 4) (Ref. 56). The prodrug BP 2-94 has significantly improved oral bioavailability and pharmacokinetic properties57. In humans, the administration of BP 2-94 results in a 100-fold increase in the amount of plasma RAMH. Moreover, in mice that receive BP 2-94 orally, high levels of both the prodrug and RAMH are detected in most tissues, except the brain57.
Replacement of the amine group of histamine by an isothiourea moiety resulted in the potent H3 receptor agonist imetit (compound 5) (pKi = 9.2, human H3 receptor)30,58,59, whereas incorporation of the flexible side chain of RAMH (compound 3) into a pyrrolidine ring or piperidine ring results in SCH50971 (compound 6) and immepip (compound 7a). Both compounds with reduced side-chain flexibility show high H3 receptor affinity (SCH50971: pKi = 8.6, guinea-pig H3 receptor; immepip: pKi = 9.3, human H3 receptor) and relatively good brain penetration60,61.
The use of RAMH (compound 3) and imetit (compound 5) as H3 receptor receptor agonists for in vivo experiments is hampered by selectivity issues, such as cardiovascular effects mediated through α2 receptors (RAMH) or 5-HT3 receptors (imetit)62 or bronchoconstriction through H1 receptor activation (RAMH)63. These selectivity issues could not be detected for immepip (compound 7a)62,64 or the pyrrolidine analogue SCH50971 (Ref. 60). However, with the recent discovery of the H4 receptor (see Ref. 2 for a recent review), it also became clear that H3 receptor agonists such as immepip, RAMH and imetit show only a limited selectivity (27–55-fold) for the H3 receptor over the related H4 receptor. Additional efforts by our research group, in collaboration with UCB Pharma (Belgium), resulted in an immepip analogue with a less basic pyridine ring in the side chain (compound 8, immethridine, pKi = 9.1, human H3 receptor). Although slightly less active than immepip at the H3 receptor, immethridine shows a 300-fold selectivity over the related human H4 receptor65. Moreover, simple N-methylation of the piperidine ring of immepip results in methimepip (compound 9), which combines high-affinity for the H3 receptor (pKi = 9.0, human H3 receptor) with a 2,000-fold selectivity over the human H4 receptor and in vivo brain penetration, as shown by a reduction in histamine levels after intraperitoneal (5 mg per kg) administration to rats66,67.
Initially, the potent H3 receptor ligand impentamine (compound 10) was identified as an H3 receptor antagonist, using the guinea-pig jejunum as a functional H3 receptor assay68. However, subsequent studies using recombinant human H3 receptors, as well as in vivo microdialysis to measure hypothalamic histamine release in the rat brain, have revealed the H3 receptor agonistic properties of impentamine69.
Intriguingly, alkylation of the amino group of impentamine with relatively simple reagents resulted in H3 receptor ligands that cover the complete range of pharmacological activity69 on recombinant human H3 receptors. By analogy, the pharmacological activity varies greatly for many of the derivatives of 3-(1H-imidazol-4-yl)propanol. Some of these compounds, such as FUB 475 (compound 11), are potent agonists in vivo (albeit PARTIAL AGONISTS in vitro), whereas close structural analogues have very different pharmacological H3 receptor activities70. A more recent example of structural fine-tuning to convert ligands from H3 receptor antagonists into H3 receptor agonists is in the aryloxypropylimidazoles series. In this class, substituents on the aryl ring have a major effect on pharmacological activity, and only the compound that has a CF3 group in the meta position (compound 12) has full H3 receptor agonist activity in vivo71.
H 3 receptor agonists as future drugs?
H3 receptor agonists might be of therapeutic use in both the CNS and the peripheral nervous system. Histaminergic neurons in the HYPOTHALAMUS are thought to have an important role in the regulation of sleep/ wakefulness72. Histamine, acting on H1 receptors, promotes a waking state, and the blockade of its action by brain-penetrating H1 receptor antagonists results in the known sedative side effects73. H3 receptor activation in the CNS results in lower hypothalamic histamine release, and H3 receptor agonists have therefore been suggested to be of use against insomnia72. Indeed, studies in various preclinical models with the RAMH prodrug BP 2-94 (compound 4) (Bioproject)72, and the H3 receptor agonist SCH50971 (compound 6) (Schering)74, confirm that sleep is induced by H3 receptor agonists.
Studies by Hough and co-workers have revealed an antinociceptive role for spinal histamine H3 receptors (Ref. 75). Intrathecally administered immepip (compound 7a) produced maximal antinociception on the tail-pinch test in wild-type, but not in histamine H3 receptor−/−, mice75. Whereas the H3 receptor agonists immepip and BP 2-94 induce antinociception in rats on a mechanical test (tail pinch), the formalin test or nociceptive responses on a thermal test (tail flick) were not affected57,75. Although histamine H3 receptor agonists seem to show antinociceptive activity on some forms of nociception, further studies are needed to evaluate the pain-relieving potential of these drugs.
H3 receptors are also known to be present on sympathetic nerve endings in the human heart76. Recent evidence from Levi and co-workers indicates that H3 receptor activation modulates ischaemic noradrenaline release in animals and in a human model of protracted myocardial ischaemia. The reduction of cardiac noradrenaline release is considered to be the mechanistic basis for the observed H3 receptor agonist-induced alleviation of reperfusion-induced arrhythmias in isolated guinea-pig hearts76. In support of this idea, recent studies in H3 receptor−/− mice have shown an increase in noradrenaline release and reperfusion arrhythmias induced by ischaemia77. As excessive noradrenaline release is regarded as an important cause of cardiac arrhythmias in humans, H3 receptor agonists could be an attractive new approach for preventing and treating myocardial ischaemic arrhythmias76.
Finally, H3 receptor agonists such as RAMH (compound 3) or its prodrug BP 2-94 (compound 4) and SCH 50791 (compound 6) are reported to inhibit neurogenic inflammatory processes in various tissues, including the lungs and dura matter57,74,78,79. These observations indicate a potential use of H3 receptor agonists in inflammation, asthma and migraine. However, in a randomized, double-blind, crossover study with six mildly asthmatic subjects, no effect of RAMH (10 mg) on bronchoconstriction induced by the inhaled irritant sodium metabisulphite was observed80. These results could be explained by the poor RAMH pharmacokinetics in humans57 and/or residual H1 receptor activity63. Phase II clinical trials with the RAMH prodrug BP 2-94 (compound 4)81 have so far resulted in negative outcomes in exercise-induced asthma or migraine82. Interestingly, in an open clinical trial, Nα-methylhistamine (compound 2) was reported to reduce headache intensity, frequency and duration in 18 patients with migraine. At the highest dose tested, however, patients reported intense headaches, which were possibly caused by residual H1 receptor agonistic effects83. Studies with more selective H3 receptor agonists, which have no residual H1 receptor agonism, should further clarify the clinical potential of H3 receptor agonists.
Histamine H 3 receptor antagonists
Many pharmaceutical companies have put considerable resources into the development of H3 receptor antagonists for various indications. As can be judged from recent (patent) literature, current players in the field include Abbott Laboratories, Boehringer Ingelheim, De Novo Pharmaceutical, Eli Lilly, GlaxoSmithKline, Johnson & Johnson PRD/Ortho-McNeil, Merck, Novo Nordisk, Pfizer, Sanofi-Synthelabo, Schering-Plough and UCB Pharma. The development of H3 receptor antagonists has recently been extensively reviewed (including patent literature)84,85,86. In the following sections, we highlight the most important frequently used H3 receptor reference compounds and some recently described compounds, for which detailed pharmacology has recently been published.
Imidazole-containing H3 receptor antagonists. The first potent H3 receptor antagonist to be described that lacked H1 receptor and H2 receptor activity was thioperamide (compound 13) (Fig. 3)55,87. More recently, however, this and many other compounds that were initially identified as H3 receptor antagonists have had to be re-classified as inverse H3 receptor agonists (Box 2). Thioperamide (compound 13) has been used as a reference H3 antagonist for almost two decades, and many preclinical studies have been carried out with this compound. Thioperamide shows high affinity for the rat H3 receptor (pKi = 8.4), but proved to be less active at the human H3 receptor (pKi = 7.2)30. At the same time, thioperamide shows high activity at the human H4 receptor (pKi = 7.3), the rat 5-HT3 receptor (pKi = 5.6) and α2A receptor (pKi = 6.9) and the human α2C receptor (pKi = 6.5)88.
Another early imidazole-containing H3 receptor antagonist that has been extensively used to characterize the H3 receptor is clobenpropit (compound 14)59. Clobenpropit (pKi = 9.4, human H3 receptor) can be considered as an imetit analogue (compound 5) and illustrates a trend in the structure–activity relationships (SARs) for H3 receptor antagonists — that is, by increasing the distance between the basic moieties of agonists (for example, histamine or imetit) and/or the attachment of larger lipophilic moieties in the side chain, potent H3 receptor antagonists can be obtained. The basic moieties in the imidazole side chain can, however, be omitted, as shown by compounds of the proxyfan class. Proxyfan (compound 15) has recently been identified as a neutral H3 receptor antagonist (pKi = 8.0, rat H3 receptor; see also Box 2; Ref. 25). However, proxyfan is a peculiar H3 receptor ligand, because it shows both H3 receptor agonistic, neutral H3 receptor antagonistic and inverse H3 receptor agonistic properties, depending on the signalling assay used43,89. As such, proxyfan is considered to be a protean agonist. Relatively small structural modifications can significantly alter its mode of action, as, for example, in the case of the compound ciproxifan (compound 16), which is a potent INVERSE AGONIST (pKi = 9.2, rH3 receptor)90,91. The ether functionality of the proxyfan class of compounds can readily be replaced by, for example, carbamates, esters, amides92 and even simple methylene units, resulting in 4-(ω-phenylalkyl)-1H-imidazoles that act as H3 receptor ligands93,94. Ciproxifan has been extensively used in various in vivo studies, but shows only a moderate affinity for the human H3 receptor (pKi = 7.2) and moderate activity for the rat 5-HT3 receptor (pKi = 6.5) and human α2A (pKi = 7.4) and α2C receptors (pKi = 7.2)88.
Several research groups have tried to make more rigid H3 receptor antagonists, thereby increasing their drug-likeness. Scientists at Gliatech incorporated the 4(5)-imidazole substituent in a cyclopropane ring and acetylene moiety. The resulting compound — cipralisant or GT2331 (compound 17) (Fig. 3) — is a high-affinity H3 receptor ligand (pKi = 9.9, rat H3 receptor) that has an imidazole heterocycle and also has a very rigid lipophilic tail attached to the 4(5)-position of the ring95. Considering the limited conformational freedom of the compound, the shape of the lipophilic group is well optimized to fit the H3 receptor binding site. Recently, some controversy about the absolute configuration of the cyclopropane ring of GT2331 has emerged. The absolute configuration (1R,2R) as reported by the developers was reassigned to (1S,2S) by Abbott scientists after re-synthesis and X-ray crystallographic analysis96. Similar to other imidazole-containing H3 antagonists, GT2331 shows a lower affinity at the human H3 receptor (pKi = 8.4) and good activity for the human H4 receptor (pKi = 7.1) and α2C receptor (pKi = 8.0)88. Moreover, in recombinant systems, GT2331 acts as an agonist at both rat and human H3 receptors, therefore calling into question the molecular mechanism of action of this H3 receptor ligand28.
Schering-Plough has also successfully developed H3 receptor antagonists in which the imidazole side chain is made relatively more rigid and lipophilic by incorporating a phenyl ring into the imidazole side chain, resulting in the lead compound SCH79687 (compound 18). The urea moiety of this compound further reduces its flexibility and gives it a shape that fits the H3 receptor binding site well, as shown by its high affinity (pKi = 8.7, rat H3 receptor). In the publications that describe the hit-optimization process that led to SCH79687 (compound 18)97, Aslanian and co-workers acknowledge the accuracy and predictive power of a PHARMACOPHORE model that was derived for imidazole-containing H3 receptor antagonists in 2001 (Ref. 98). Using state-of-the-art partial similarity tools99, a model was developed that describes the relative position and orientation of four hydrogen-bonding site points, an imidazole-binding pocket and two hydrophobic pockets that are available for binding various classes of H3 receptor antagonist. This work has resulted in the imidazole-containing compound 19, which has excellent affinity for both the H1 receptor and H3 receptor (pKi = 7.8 and 8.2, respectively)100.
Non-imidazole H3 receptor antagonists. Most of the imidazole-containing antagonists (thioperamide, clobenpropit and ciproxifan) interact with cytochrome P450 (Refs 101,102). As such an interaction is unwanted in drug development, many research groups have been developing non-imidazole H3 receptor antagonists.
The first two successful efforts to develop non-imidazole H3 receptor antagonists were reported by academic research groups in 1998, 15 years after the discovery of the receptor. The work of Ganellin and co-workers resulted in UCL1972 (compound 20, see Fig. 4), a compound with reasonable H3 receptor affinity (pKi = 7.4, rat H3 receptor), good oral bioavailability and good penetration of the blood–brain barrier (BBB)103. In the same year, Menge and co-workers104 reported non-imidazole H3 receptor antagonists that were based on sabeluzole, a drug used to treat Alzheimer's disease. The weak H3 receptor affinity of sabeluzole could be optimized, leading to VUF5391 (compound 21) — a ligand with good H3 receptor affinity (pKi = 8.2, rat H3 receptor). Later, Stark and co-workers modified imidazole-containing lead structures, resulting in, among others, the potent compound FUB 649 (compound 22) (pKi = 7.8, rat H3 receptor)105. These studies showed that for some classes of imidazole-containing antagonist, the heterocycle can be replaced by other basic groups, mainly cyclic amines. However, these simple substitutions are not successful for all classes of antagonist, which could be indicative of partial similarity in the binding mode of the different classes of antagonist97.
More recently, several major pharmaceutical companies have published their efforts to develop non-imidazole H3 receptor antagonist drugs. Abbott Laboratories described their optimization of a high-throughput screening (HTS) hit, which led to A-317920 (compound 23), a very potent ligand on the rat H3 receptor (pKi = 9.2). In addition, the compound has good oral bioavailability88. Unfortunately, it was found that the affinity for the human H3 receptor was significantly lower (pKi = 7.0), again showing the important H3 receptor species differences (see above). Nevertheless, A-317920 (compound 23) contains some typical structural features of H3 receptor antagonists — that is, the propyloxy chain that connects a basic group with a phenyl ring, the acylpiperazine and the cyclopropylketone terminus. Additional medicinal chemistry efforts to optimize the affinity for human H3 receptors resulted in the biphenyl compound A-331440 (compound 24). This compound has a higher affinity for the human H3 receptor than for the rat H3 receptor (pKi = 8.6 and 7.8, respectively)106. A-331440 acts as a selective inverse agonist at the human H3 receptor. Interestingly, A-331440 shows considerably higher inverse agonistic efficacy than ciproxyfan and thioperamide91. At the same time, A-331440 shows 35% oral bioavailability (rat) and has a far greater brain/plasma ratio than ciproxyfan (45-fold) and thioperamide (666-fold).
In an attempt to make the non-imidazole H3 receptor antagonists more rigid, the flexible propyloxy chain was partly incorporated into a fused aromatic system, resulting in benzofuran-containing compounds. The selected compound from this series, ABT-239 (compound 27), shows excellent affinities for the human and rat H3 receptors (pKi = 9.3 and 8.9, respectively), a lack of affinity for 80 non-H3 receptor targets, potent inverse H3 receptor agonism and good CNS penetration (brain/plasma ratio >30)107,108. This compound is intended for the treatment of cognitive disorders (see below) and has recently entered Phase I clinical trials109.
Recently, Cowart reported SAR studies of ABT-239-like compounds. The benzofuran core can be linked to many amines107,110. For good activities, the pyrrolidines can also be substituted at the 2-position, with groups such as methyl ((R)-isomer in ABT-239), ethyl, fluorinated alkyls, methoxy or amines. The terminal phenyl ring of ABT-239 can be replaced by heterocycles and/or further substituted. Several of these compounds can serve as back-up compounds for ABT-239 (Ref. 110).
Scientists at Johnson & Johnson PRD have also optimized HTS hits into a series of non-imidazole lead compounds that contain two basic groups, typically cyclic amines separated by a relatively simple linker. This arrangement is becoming a recurring theme in H3 receptor (patent) literature. The potent lead compound JNJ-5207852 (compound 28) (pKi = 9.5, human H3 receptor) developed by Johnson & Johnson PRD readily crosses the BBB and has good oral bioavailability111. Recently, the phenylalkyne JNJ-10181457 (compound 29) (pKi = 9.1, human H3 receptor) was selected for detailed in vivo evaluation on the basis of a favourable pharmacokinetic and brain-residency profile. Plasma and brain concentrations in rats following an oral dose of 10 mg per kg reached a level of 10 μM112.
In a combinatorial chemistry approach, Novo Nordisk prepared a library of monoacyl diamines. Acylpiperazines were identified as initial hits and were quickly optimized using parallel chemistry efforts, leading to the high-affinity compound 30 (pKi = 9.4). More recently, Novo Nordisk described a series of cinnamic amides of aminomethylpyrrolidines, leading to the discovery of NNC 0038-0000-1202 (compound 31) as a potent (pKi = 8.3) antagonist/inverse agonist for the human H3 receptor. This compound has a good selectivity for the other three histamine receptors and more than 70 other targets (Kis >10 μM). Only some cross-reactivity of NNC 0038-0000-1202 (compound 31) with both 5-HT1A and σ receptors, and the sodium channel, was observed113.
Therapeutic uses of H 3 receptor antagonists
Despite the large number of non-imidazole H3 receptor antagonists that have appeared in patent literature in the past 5 years (see Ref. 85 for a detailed review), only a few reports of their preclinical use have so far been made. In the next sections, we review several of the most promising applications for H3 receptor antagonists. For much of this information, we still rely to a large extent on the observed effects of the 'early' imidazole-containing H3 antagonists.
Peripheral H3 receptor blockade in nasal congestion. Allergic rhinitis is a frequently occurring chronic disease that affects a large number of people. In patients who are allergic, mast-cell histamine is one of the crucial mediators involved in, for example, pruritus, mucus secretion and the regulation of vascular permeability through activation of the H1 receptor114. Recent analysis of H3 receptor expression in the periphery by quantitative PCR revealed that H3 receptor mRNA is abundantly expressed in human nasal mucosa; H3 receptors modulate vascular contractile responses by the inhibition of noradrenaline release from sympathetic nerve terminals in the nasal mucosa115. In addition, in a cat model of nasal decongestion, a combination of either thioperamide (1–10 mg per kg intravenously (i.v.)) or clobenpropit (0.03–1 mg per kg i.v.) with the H1 receptor antagonist chlorpheniramine resulted in significant nasal decongestion without the hypertensive effect seen with adrenergic agonists116. On the basis of these data, Schering seems to be actively pursuing combined H1 and H3 receptor blockade as a novel approach for nasal decongestion. The imidazole-based H3 receptor antagonist SCH79687 (compound 18) (Fig. 3) hardly enters the brain (brain/plasma ratio = 0.02), but in combination with the H1 receptor antagonist loratadine (10 mg per kg per os (p.o.)), SCH9687 inhibited the decrease in nasal cavity volume due to aerosolized compound 48/80 (a mast-cell destabilizer)114. The dual H1/H3 receptor antagonist 19 (Ref. 100) has been developed for the same indication, but, at present, no in vivo data are available for this ligand.
Central H3 receptor blockade in obesity. With the increasing incidence of obesity and diabetes and associated health risks in modern Western society117, the need for the development of new anti-obesity drugs is rapidly growing. Modulation of CNS histaminergic neurotransmission represents an interesting new mechanism to control body weight. The role of neuronal histamine in food intake has been established for many years (see Refs 84,118 for extensive reviews), and the blockade of its action at hypothalamic H1 receptors has been indicated as the mechanistic action of weight gain after therapy with, for example, various antipsychotics119. Moreover, neuronal histamine release and/or signalling has also been implicated in the anorectic actions of known mediators in the feeding cycle (for example, leptin, amylin and bombesin)84.
As mentioned, in the brain, the H3 receptor is implicated in the regulation of histamine release in the hypothalamus. Moreover, recent in situ hybridization studies revealed H3 receptor mRNA expression in rat brown adipose tissue120, indicating that H3 receptor ligands might (peripherally) regulate thermogenesis. On the basis of these notions and the observations that in the CNS H3 receptor antagonists elevate hypothalamic histamine levels61,121, it can be understood why the anti-obesity potential of H3 receptor antagonists has attracted considerable attention. Studies with the imidazole-containing H3 receptor antagonist thioperamide (compound 13) or ciproxyfan (compound 16) provide evidence for the modulatory role of the H3 receptor in feeding behaviour. In various models of acute food intake, these H3 receptor antagonists have been reported to be effective84, although a recent study indicated that the effects of thioperamide might be related to visceral discomfort122.
Recently, non-imidazole-containing H3 receptor antagonists have been investigated in various preclinical models of obesity. Obesity induced by a high-fat diet in mice was effectively reduced by the non-imidazole H3 receptor antagonist, but not by ciproxifan91. A 28-day treatment regimen of 5 mg per kg p.o. A-331440 reduced weight at a similar level to dexfenfluramine (10 mg per kg p.o.), and a higher dose of 15 mg per kg reduced weight to a level of mice on a low-fat diet. Magnetic resonance imaging analysis indicated that dexfenfluramine treatment (10 mg per kg p.o.) did not reduce body fat, whereas the H3 receptor antagonist treatment resulted in a significant reduction of total, abdominal and subcutaneous fat91. In various animal models of obesity, A-331440 showed anti-obesity efficacy, including a reduction in food intake and a lowering of circulating leptin and ghrelin levels84. Despite the favourable anti-obesity properties of A-331440, further preclinical development was halted because the drug scored positively in an in vitro micronucleus test for potential genotoxicity123. However, 3′-fluoro (compound 25, A-417022) or 3′,5′-difluoro (compound 26, A-423579) substitution of the biphenyl moiety (Fig. 4) results in compounds with nanomolar affinities but no in vitro genotoxic effects. The difluoro analogue A-423579 (10 mg per kg) reduced body weight, plasma leptin, energy intake and body fat mass in treatment for 14–28 days of diet-induced obese rodents123. In these models, A-423579 was as effective as the mixed 5-HT/noradrenaline reuptake inhibitor sibutramine (5 mg per kg) and did not affect the behavioural satiety sequence in rats, indicating that the effects are not due to visceral illness or taste aversion123.
Besides Abbott Laboratories, Novo Nordisk is also aiming to develop non-imidazole H3 receptor antagonists as anti-obesity drugs. In rats, their lead compound NNC 0038-0000-1202 (compound 31) showed an 85% oral availability, and microdialysis experiments showed a clear dose-dependent (compound 7, 5–30 mg per kg p.o.) release of histamine in the paraventricular nucleus of the rat hypothalamus after oral administration of NNC 0038-0000-1202. Moreover, in rodents, pigs and monkeys this H3 receptor antagonist decreases food intake, and, in rodents, also body weight. At the same time, the compound was well tolerated and did not affect either the behavioural satiety sequence or locomotion of rats124. Additional H3 receptor antagonists with higher efficacy and tolerability have been announced by Novo Nordisk, but in vivo results have so far not been presented.
On the basis of these data from preclinical models, the blockade of H3 receptors by selective antagonists or inverse H3 receptor agonists might be an attractive mechanism of action for anti-obesity compounds. H3 receptor blockers reduce weight gain, lower plasma ghrelin and leptin levels, and seem to be well tolerated. As the compounds probably do not induce stimulatory behaviour, unlike amphetamine-like stimulants84, clinical data on H3 receptor antagonists in human obesity are eagerly awaited, but, at present, no clinical trials in this area have been announced.
Central H3 receptor blockade in sleep and cognitive disorders. It is well known that many of the first-generation, brain-penetrating H1 receptor antagonists cause sedation and a decline in cognitive functions125,126. Consequently, indirect modulation of histaminergic brain function by H3 receptor antagonists might be a means to modulate attention and memory processes. Whereas H3 receptor agonists induce sleep in preclinical animal models (see above), thioperamide increases wakefulness in wild-type mice, but has no effect on sleep/wakefulness in H3 receptor−/− mice38. Moreover, ciproxyfan significantly decreases slow-wave electroencephalographic activity, which is indicative of sleep, in both rats and cats90,127. These data indicate that H3 receptor antagonists promote wakefulness. Therefore, H3 receptor antagonists might be useful in sleep-related disorders, such as NARCOLEPSY. Interestingly, modafinil (Modiodal/Provigil; Organon/ Cephalon), a novel wakefulness-promoting drug for the treatment of narcolepsy has recently been shown to increase hypothalamic histamine release128, and recent studies using the classic Doberman model of narcolepsy with either GT2331 (compound 17)129 or the non-imidazole H3 receptor antagonist JNJ-10181457 (compound 29) showed that H3 receptor antagonists reduce the number of narcoleptic attacks and the duration of the attacks112.
In various neuropsychiatric conditions (for example, attention-deficit hyperactivity disorder (ADHD), schizophrenia and Alzheimer's disease), cognitive deficits are an integral part of the disease. It is therefore of huge interest that a variety of H3 receptor antagonists can improve cognitive performance in various animal models (see Ref. 130 for a recent review). The reported neuromodulatory role of the histaminergic system on acetylcholine release is important in this respect131. For example, thioperamide increases in vivo acetylcholine in the rat hippocampus132 and enhances recall of a passive avoidance response in rats133 and senescence-accelerated mice134. It also improves short-term memory in a novel-object-recognition test133 and social recognition test135. In addition, the imidazole-containing H3 receptor antagonists ciproxyfan and GT2331 improve acquisition in an inhibitory avoidance model with rat pups136. On the basis of these observations, the imidazole-containing compound GT2331 (Gliatech) has reached clinical trials129. However, the development of this drug for the treatment of ADHD has been halted in Phase II trials for unknown reasons at present.
In view of the reported agonistic activity of GT2331 at recombinant H3 receptors and the limited selectivity towards the α2C receptor, for example (see above), some of the newer, highly selective non-imidazole H3 receptor antagonists/inverse agonists might have improved characteristics for use in cognitive disorders. Abbott Laboratories recently reported that in a rat pup model for ADHD, A-317920 (compound 23) was at was least as effective as methylphenidate (Ritalin; Novartis) (a stimulant) or ABT-418 (a nicotine-receptor ligand), which are both clinically effective ADHD drugs130. Moreover, the highly selective H3 receptor ligand ABT-239 (compound 27) has entered Phase I clinical trials after promising activities in preclinical models of ADHD and Alzheimer's disease. In rats, ABT-239 enhances acetylcholine release in the prefrontal cortex and the hippocampus110, improves learning in a five-trial inhibitory avoidance model using rat pups (a model of ADHD), improves recall in a social memory test, and improves spatial working and reference memory in a water maze at dose ranges of 0.01–1 mg per kg subcutaneously137,138. Moreover, a second H3 receptor antagonist (ABT-834) developed by Abbott Laboratories has recently entered Phase I studies and is also supposed to target cognitive dysfunction109. At present, neither structural nor biological data for ABT-834 have been disclosed.
Researchers at Johnson & Johnson PRD reported on preclinical effects of JNJ-10181457. The compound showed pro-arousal effects in rats after subcutaneous dosing (half-maximal effective dose (ED50) = 0.3 mg per kg). An improvement in the memory performance of juvenile rats (passive avoidance in spontaneous hypertensive rat (SHR)) was reported at a dose of 10 mg per kg intraperitoneally112.
Finally, scientists at GlaxoSmithKline recently reported on a high-affinity (pKi = 9.7 and 8.7 for human H3 and rat H3, respectively) non-imidazole H3 receptor antagonist, with strong inverse agonistic properties139. The structure of GSK189254A was not revealed, but the compound effectively reached the brain and showed pro-cognitive effects at 0.3–1 mg per kg in a novel-object-recognition test139.
On the basis of the various preclinical data on various (non)-imidazole H3 receptor antagonists, the H3 receptor seems to be an interesting target for improving attention and alleviating cognitive dysfunction in, for example, ADHD and Alzheimer's disease. Results of a clinical trial with one of the many non-imidazole H3 receptor antagonists are eagerly awaited.
Get smart and get slim? The preclinical findings indicate that H3 receptor antagonists might become future 'wonder drugs'. H3 receptor antagonists are promising effective anti-obesity drugs that, at the same time, could improve cognitive performance. However, this promise has not yet been fulfilled.
A close look at the H3 receptor ligands recently described by Abbott laboratories, for example, shows that different molecules are presented for either anti-obesity (such as A-331440) or pro-cognitive effects (ABT-239). At the recent annual meeting of the European Histamine Research Society (Düsseldorf/ Köln, 2004), this issue was discussed in some detail, and it seems that H3 receptor antagonists that are active in anti-obesity models do not always work in models of cognition and vice versa. These observations were supported by results from scientists at GlaxoSmithKline and Novo Nordisk, indicating that H3 receptor blockade and BBB passage alone are not enough to obtain both in vivo effects. Explanations for the observed discrepancy are currently not available, although several possibilities can be considered. Potential explanations might relate to the complexity of H3 receptor isoform expression and H3 receptor signalling, including constitutive activity. Could different H3 receptor isoforms or signal-transduction pathways with varying drug sensitivity be involved in the diverse effects? MAPK activation seems to be involved in H3 receptor-mediated memory processes42, but, so far, the molecular pathway(s) involved in the anti-obesity effects of H3 receptor antagonists have not been studied. Recent studies of a series of GT2331 analogues have indicated that inverse H3 receptor antagonists, but not neutral H3 receptor antagonists, would be effective in obesity models140. However, it is not yet clear whether these observations can be generalized. It is also possible that besides potent H3 receptor blockade, other (receptor) activities are needed to observe the various in vivo effects or that drug penetration in important brain areas would be different and therefore result in different in vivo efficacy profiles. At present, none of these possibilities can be excluded and further research is needed.
Concluding remarks
In the past 5 years, much progress has been made in the understanding of the H3 receptor at the molecular level. Moreover, many potent and relatively selective H3 receptor agonists and inverse agonists have been developed by various academic and industrial scientists. For both H3 receptor agonists and H3 receptor inverse agonists/antagonists, many interesting activities in several preclinical models of important human diseases have been reported. Results from clinical trials are currently awaited, and will be the next step in the process of moving from knowledge of the gene encoding the H3 receptor to the development of drugs for a range of indications. At the same time, important questions about the molecular aspects, biology and pathophysiology of the H3 receptor remain to be answered to form a solid scientific basis for the therapeutic application of H3 receptor ligands.
References
Ma, P. & Zemmel, R. Value of novelty? Nature Rev. Drug Discov., 1, 571–572 (2002).
Hough, L. B. Genomics meets histamine receptors: new subtypes, new receptors. Mol. Pharmacol. 59, 415–419 (2001).
Arrang, J. M., Garbarg, M. & Schwartz, J. C. Auto-inhibition of brain histamine release mediated by a novel class (H3) of histamine receptor. Nature 302, 832–837 (1983). The first description of the histamine H 3 receptor in rat brain on the basis of pharmacological data.
Haas, H. & Panula, P. The role of histamine and the tuberomamillary nucleus in the nervous system. Nature Rev. Neurosci. 4, 121–130 (2003). Timely review on the role of histamine in the brain.
Lovenberg, T. W. et al. Cloning and functional expression of the human histamine H3 receptor. Mol. Pharmacol. 55, 1101–1107 (1999). First identification of the H 3 receptor as a G-protein coupled receptor.
Drutel, G. et al. Identification of rat H3 receptor isoforms with different brain expression and signaling properties. Mol. Pharmacol. 59, 1–8 (2001). Description of H 3 receptor isoforms with different localization and signal transduction efficiencies.
Héron, A. et al. Expression analysis of the histamine H3 receptor in developing rat tissues. Mech. Dev. 105, 167–173 (2001).
Pollard, H. et al. A detailed autoradiographic mapping of histamine H3 receptors in rat brain areas. Neuroscience 52, 169–189 (1993).
Chazot, P. L. et al. Immunological identification of the mammalian H3 histamine receptor in the mouse brain. Neuroreport 12, 259–262 (2001).
Leurs, R. et al. H3 receptor gene is cloned at last. Trends Pharmacol. Sci. 21, 11–12 (2000).
Gantz, I. et al. Molecular cloning of a gene encoding the histamine H2 receptor. Proc. Natl Acad. Sci. USA 88, 429–433 (1991).
Yamashita, M. et al. Expression cloning of a cDNA encoding the bovine histamine H1 receptor. Proc. Natl Acad. Sci. USA 88, 11515–11519 (1991).
Oda, T. et al. Molecular cloning and characterization of a novel type of histamine receptor preferentially expressed in leukocytes. J. Biol. Chem. 275, 36781–36786 (2000). Identification of the histamine H 4 receptor, which shows high similarity to the H 3 receptor. Many classical H 3 receptor ligands also bind to the H 4 receptor.
Nakamura, T. et al. Molecular cloning and characterization of a new human histamine receptor, HH4R. Biochem. Biophys. Res. Commun. 279, 615–620 (2000).
Liu, C. et al. Cloning and pharmacological characterization of a fourth histamine receptor (H4) expressed in bone marrow. Mol. Pharmacol. 59, 420–426 (2001).
Morse, K. L. et al. Cloning and characterization of a novel human histamine receptor. J. Pharmacol. Exp. Ther. 296, 1058–1066 (2001).
Zhu, Y. et al. Cloning, expression, and pharmacological characterization of a novel human histamine receptor. Mol. Pharmacol. 59, 434–441 (2001).
Nguyen, T. et al. Discovery of a novel member of the histamine receptor family. Mol. Pharmacol. 59, 427–433 (2001).
Hancock, A. A. et al. Genetic and pharmacological aspects of histamine H3 receptor heterogeneity. Life Sci. 73, 3043–3072 (2003). This paper summarizes available information on H 3 receptor isoforms.
Wiedemann, P. et al. Structure of the human histamine H3 receptor gene (HRH3) and identification of naturally occurring variations. J. Neural Transm. 109, 443–453 (2002).
Wellendorph, P. et al. Molecular cloning and pharmacology of functionally distinct isoforms of the human histamine H3 receptor. Neuropharmacology 42, 929–940 (2002).
Cogé, F. et al. Genomic organization and characterization of splice variants of the human histamine H3 receptor. Biochem. J. 355, 279–288 (2001).
Liu, C., Ma, X. J. & Lovenberg, T. W. Alternative splicing of the histamine H3 receptor mRNA at the third cytoplasmic loop is not detectable in humans. Brain Res. Mol. Brain Res. 83, 145–150 (2000).
Shenton, F. et al. Human H3 receptor isoforms can form homooligomers. XXXIII Ann. Meet. Eur. Histamine Res. Soc. Abs. P104 (2004).
Morisset, S. et al. High constitutive activity of native H3 receptors regulates histamine neurons in brain. Nature 408, 860–864 (2000). The H 3 receptor is one of the few GPCRs shown to exert high levels of constitutive signalling in native tissues.
Yao, B. B. et al. Molecular modeling and pharmacological analysis of species-related histamine H3 receptor heterogeneity. Neuropharmacology 44, 773–786 (2003).
Coge, F. et al. Genomic organization and characterization of splice variants of the human histamine H3 receptor. Biochem. J. 355, 279–288 (2001).
Wulff, B. S., Hastrup, S. & Rimvall, K. Characteristics of recombinantly expressed rat and human histamine H3 receptors. Eur. J. Pharmacol. 453, 33–41 (2002).
Morisset, S. et al. The rat H3 receptor: gene organization and multiple isoforms. Biochem. Biophys. Res. Commun. 280, 75–80 (2001).
Lovenberg, T. W. et al. Cloning of rat histamine H3 receptor reveals distinct species pharmacological profiles. J. Pharmacol. Exp. Ther. 293, 771–778 (2000).
Tardivel-Lacombe, J. et al. Cloning and cerebral expression of the guinea pig histamine H3 receptor: evidence for two isoforms. Neuroreport 11, 755–759 (2000).
Cassar, S. Cloning of the guinea pig H3 receptor. Neuroreport 11, L3–L4 (2000).
Chen, J., Liu, C. & Lovenberg, T. W. Molecular and pharmacological characterization of the mouse histamine H3 receptor. Eur. J. Pharmacol. 467, 57–65 (2003).
Yao, B. B. et al. Cloning and pharmacological characterization of the monkey histamine H3 receptor. Eur. J. Pharmacol. 482, 49–60 (2003).
Ireland-Denny, L. et al. Species-related pharmacological heterogeneity of histamine H3 receptors. Eur. J. Pharmacol. 433, 141–150 (2001).
Tardivel-Lacombe, J. et al. Chromosomal mapping and organization of the human histamine H3 receptor gene. Neuroreport 12, 321–324 (2001).
Rouleau, A. et al. Cloning and expression of the mouse histamine H3 receptor: evidence for multiple isoforms. J. Neurochem. 90, 1331–1338 (2004).
Toyota, H. et al. Behavioral characterization of mice lacking histamine H3 receptors. Mol. Pharmacol. 62, 389–397 (2002).
Takahashi, K. et al. Targeted disruption of H3 receptors results in changes in brain histamine tone leading to an obese phenotype. J. Clin. Invest. 110, 1791–1799 (2002). References 38 and 39 report initial results with H 3 receptor knockout mice.
Chazot, P. L. & Shenton, F. C. H3 Histamine receptors: the gene knockout data so far. Curr. Anaesth. Crit. Care 15, 23–28 (2004).
Clark, E. A. & Hill, S. J. Sensitivity of histamine H3 receptor agonist-stimulated [35S]GTP?S binding to pertussis toxin. Eur. J. Pharmacol. 296, 223–225 (1996).
Giovannini, M. G. et al. Improvement in fear memory by histamine-elicited ERK2 activation in hippocampal CA3 cells. J. Neurosci. 23, 9016–9023 (2003).
Rouleau, A. et al. Histamine H3-receptor-mediated [35S]GTPγS binding: evidence for constitutive activity of the recombinant and native rat and human H3 receptors. Br. J. Pharmacol. 135, 383–392 (2002).
Silver, R. B. et al. Coupling of histamine H3 receptors to neuronal Na+/H+ exchange: a novel protective mechanism in myocardial ischemia. Proc. Natl Acad. Sci. USA 98, 2855–2859 (2001).
Silver, R. B. et al. Decreased intracellular calcium mediates the histamine H3-receptor-induced attenuation of noradrenaline exocytosis from cardiac sympathetic nerve endings. Proc. Natl Acad. Sci. USA 99, 501–506 (2002).
Molina-Hernandez, A. et al. Histamine H3 receptor activation inhibits glutamate release from rat striatal synaptosomes. Neuropharmacology 41, 928–934 (2001).
Bongers, G. et al. Modulation of Akt/GSK3-β axis as new signaling properties of the histamine H3 receptor. XXXIII Ann. Meet. Eur. Histamine Res. Soc. Abs. P25 (2004).
Sun, W. et al. Glycogen synthase kinase-3β is complexed with tau protein in brain microtubules. J. Biol. Chem. 277, 11933–11940 (2002).
Lin, C. H. et al. A role for the PI-3 kinase signaling pathway in fear conditioning and synaptic plasticity in the amygdala. Neuron 31, 841–851 (2001).
Gomez-Ramirez, J., Ortiz, J. & Blanco, I. Presynaptic H3 autoreceptors modulate histamine synthesis through cAMP pathway. Mol. Pharmacol. 61, 239–245 (2002).
Jope, R. S. & Johnson, G. V. The glamour and gloom of glycogen synthase kinase-3. Trends Biochem. Sci. 29, 95–102 (2004).
Leurs, R., Vollinga, R. C. & Timmerman, H. The medicinal chemistry and therapeutic potentials of ligands of the histamine H3 receptor. Prog. Drug Res. 45, 107–165 (1995).
De Esch, I. J. & Belzar, K. L. Histamine H3 receptor agonists. Mini Rev. Med. Chem. 4, 955–963 (2004).
Krause, M., Stark, H. & Schunack, W. in The Histamine H3 Receptor: a Target For New Drugs (eds Leurs R. & Timmerman, H.) 175–196 (Elsevier, Amserdam, 1998).
Arrang, J. M. et al. Highly potent and selective ligands for histamine H3-receptors. Nature 327, 117–123 (1987). This paper described the discovery of ( R )-α-methylhistamine and thioperamide as a first set of relatively selective H 3 receptor ligands.
Krause, M. et al. Synthesis, X-ray crystallography, and pharmacokinetics of novel azomethine prodrugs of (R)-α-methylhistamine: highly potent and selective histamine H3 receptor agonists. J. Med. Chem. 38, 4070–4079 (1995).
Rouleau, A. et al. Bioavailability, antinociceptive and antiinflammatory properties of BP 2-94, a histamine H3 receptor agonist prodrug. J. Pharmacol. Exp. Ther. 281, 1085–1094 (1997). First description of a bioavailable H 3 receptor agonist prodrug with therapeutic potential for peripheral applications.
Garbarg, M. et al. S-[2-(4-imidazolyl)ethyl]isothiourea, a highly specific and potent histamine H3 receptor agonist. J. Pharmacol. Exp. Ther. 263, 304–310 (1992).
Van der Goot, H. et al. Isothiourea analogues of histamine as potent agonists or antagonists of the histamine H3 receptor. Eur. J. Med. Chem. 27, 511–517 (1992).
Shih, N. Y. et al. Trans-4-methyl-3-imidazoyl pyrrolidine as a potent, highly selective histamine H3 receptor agonist in vivo. Bioorg. Med. Chem. Lett. 8, 243–248 (1998).
Jansen, F. P. et al. In vivo modulation of rat hypothalamic histamine release by the histamine H3 receptor ligands, immepip and clobenpropit. Effects of intrahypothalamic and peripheral application. Eur. J. Pharmacol. 362, 149–155 (1998).
Coruzzi, G. et al. Cardiovascular effects of selective agonists and antagonists of histamine H3 receptors in the anaesthetized rat. Naunyn Schmiedebergs Arch. Pharmacol. 351, 569–575 (1995).
Hey, J. A. et al. (R)-α-methylhistamine augments neural, cholinergic bronchospasm in guinea pigs by histamine H1 receptor activation. Eur. J. Pharmacol. 211, 421–426 (1992).
Vollinga, R. C. et al. A new potent and selective histamine H3 receptor agonist, 4-(1H-imidazol-4-ylmethyl)piperidine. J. Med. Chem. 37, 332–333 (1994).
Kitbunnadaj, R. et al. Identification of 4-(1H-imidazol-4(5)-ylmethyl)pyridine (immethridine) as a novel, potent, and highly selective histamine H3 receptor agonist. J. Med. Chem. 47, 2414–2417 (2004).
Kitbunnadaj, R. et al. N-substituted piperidinyl alkyl imidazoles: discovery of methimepip as a potent and selective histamine H3 receptor agonist. J. Med. Chem. 24 Nov 2004 (10.1021/jm049475h). Description of an H 3 receptor agonist with a 2,000-fold selectivity over the H 4 receptor.
Leurs, R. Molecular pharmacology of the histamine H3 receptor. Exper. Biol. 2004. (2004).
Vollinga, R. C. et al. Homologs of histamine as histamine H3 receptor antagonists: a new potent and selective H3 antagonist, 4(5)-(5-aminopentyl)-1H-imidazole. J. Med. Chem. 38, 266–271 (1995).
Wieland, K. et al. Constitutive activity of histamine H3 receptors stably expressed in SK-N-MC cells: display of agonism and inverse agonism by H3 antagonists. J. Pharmacol. Exp. Ther. 299, 908–914 (2001).
Sasse, A. et al. Novel partial agonists for the histamine H3 receptor with high in vitro and in vivo activity. J. Med. Chem. 42, 4269–4274 (1999).
Pelloux-Leon, N. et al. Meta-substituted aryl(thio)ethers as potent partial agonists (or antagonists) for the histamine H3 receptor lacking a nitrogen atom in the side chain. J. Med. Chem. 47, 3264–3274 (2004).
Lin, J. S. Brain structures and mechanisms involved in the control of cortical activation and wakefulness, with emphasis on the posterior hypothalamus and histaminergic neurons. Sleep Med. Rev. 4, 471–503 (2000). Review describing the role of histamine and the H 3 receptor in the regulation of sleep-wakefulness.
Welch, M. J., Meltzer, E. O. & Simons, F. E. H1-antihistamines and the central nervous system. Clin. Allergy Immunol. 17, 337–388 (2002).
McLeod, R. L. et al. Sch 50971, an orally active histamine H3 receptor agonist, inhibits central neurogenic vascular inflammation and produces sedation in the guinea pig. J. Pharmacol. Exp. Ther. 287, 43–50 (1998).
Cannon, K. E. et al. Activation of spinal histamine H3 receptors inhibits mechanical nociception. Eur. J. Pharmacol. 470, 139–147 (2003).
Levi, R. & Smith, N. C. Histamine H3-receptors: a new frontier in myocardial ischemia. J. Pharmacol. Exp. Ther. 292, 825–830 (2000).
Koyama, M., Heerdt, P. M. & Levi, R. Increased severity of reperfusion arrhythmias in mouse hearts lacking histamine H3-receptors. Biochem. Biophys. Res. Commun. 306, 792–796 (2003).
Matsubara, T., Moskowitz, M. A. & Huang, Z. UK-14,304, R(-)-α-methyl-histamine and SMS 201-995 block plasma protein leakage within dura mater by prejunctional mechanisms. Eur. J. Pharmacol. 224, 145–150 (1992).
Ichinose, M., Belvisi, M. G. & Barnes, P. J. Histamine H3-receptors inhibit neurogenic microvascular leakage in airways. J. Appl. Physiol. 68, 21–25 (1990).
O'Connor, B. J., Lecomte, J. M. & Barnes, P. J. Effect of an inhaled histamine H3-receptor agonist on airway responses to sodium metabisulphite in asthma. Br. J. Clin. Pharmacol. 35, 55–57 (1993).
Fozard, J. R. BP-294 Ste Civile Bioprojet. Curr. Opin. Investig. Drugs 1, 86–89 (2000).
Schwartz, J. C. The histamine H3 receptor: from molecular pharmacology to clinical applications. IInd Int. Symp. Mol. Med. Abs. (2002).
Millán-Guerrero, R. O. et al. Nα-methylhistamine safety and efficacy in migraine prophylaxis: phase I and phase II studies. Headache 43, 389–394 (2003).
Hancock, A. A. H3 Receptor antagonists/inverse agonists as anti-obesity agents. Curr. Opin. Investig. Drugs 4, 1190–1197 (2003). Review describing the role of histamine and the H 3 receptor in food intake and the therapeutic potential of H 3 receptor antagonists as anti-obesity drugs.
Stark, H. Recent advances in histamine H3/H4 receptor ligands. Expert Opin. Ther. Patents 13, 851–865 (2003). This paper reviews the structure–activity relationships of the various H 3 receptor ligands. Information from the extensive patent literature is included as well in this review.
Howard, H. R. Agents for attention-deficit hyperactivity disorder an update. Expert Opin. Ther. Patents 14, 983–1008 (2004).
Arrang, J. M., Garbarg, M. & Schwartz, J. C. Autoinhibition of histamine synthesis mediated by presynaptic H3-receptors. Neuroscience 23, 149–157 (1987).
Esbenshade, T. A. et al. Two novel and selective nonimidazole histamine H3 receptor antagonists A-304121 and A-317920: I. In vitro pharmacological effects. J. Pharmacol. Exp. Ther. 305, 887–896 (2003).
Gbahou, F. et al. Protean agonism at histamine H3 receptors in vitro and in vivo. Proc. Natl Acad. Sci. USA 100, 11086–11091 (2003).
Ligneau, X. et al. Neurochemical and behavioral effects of ciproxifan, a potent histamine H3-receptor antagonist. J. Pharmacol. Exp. Ther. 287, 658–666 (1998).
Hancock, A. A. et al. Antiobesity effects of A-331440, a novel non-imidazole histamine H3 receptor antagonist. Eur. J. Pharmacol. 487, 183–197 (2004).
Stark, H. et al. [125I]iodoproxyfan and related compounds: a reversible radioligand and novel classes of antagonists with high affinity and selectivity for the histamine H3 receptor. J. Med. Chem. 39, 1220–1226 (1996).
Stark, H. et al. General construction pattern of histamine H3-receptor antagonists: change of a paradigm. Bioorg. Med. Chem. Lett. 8, 2011–2016 (1998).
De Esch, I. J. et al. Synthesis and histamine H3 receptor activity of 4-(n-alkyl)-1H-imidazoles and 4-(ω-phenylalkyl)-1H-imidazoles. Bioorg. Med. Chem. 7, 3003–3009 (1999).
Ali, S. M. et al. Design, synthesis, and structure–activity relationships of acetylene-based histamine H3 receptor antagonists. J. Med. Chem. 42, 903–909 (1999).
Liu, H. et al. An efficient multigram synthesis of the potent histamine H3 antagonist GT-2331 and the reassessment of the absolute configuration. J. Org. Chem. 69, 192–194 (2004).
Aslanian, R. et al. Identification of a novel, orally bioavailable histamine H3 receptor antagonist based on the 4-benzyl-(1H-imidazol-4-yl) template. Bioorg. Med. Chem. Lett. 12, 937–941 (2002).
De Esch, I. J. et al. Development of a pharmacophore model for histamine H3 receptor antagonists, using the newly developed molecular modeling program SLATE. J. Med. Chem. 44, 1666–1674 (2001).
Mills, J. E. et al. SLATE: a method for the superposition of flexible ligands. J. Comput. Aided Mol. Des. 15, 81–96 (2001).
Aslanian, R. et al. Identification of a dual histamine H1/H3 receptor ligand based on the H1 antagonist chlorpheniramine. Bioorg. Med. Chem. Lett. 13, 1959–1961 (2003).
LaBella, F. S. et al. H3 receptor antagonist, thioperamide, inhibits adrenal steroidogenesis and histamine binding to adrenocortical microsomes and binds to cytochrome P450. Br. J. Pharmacol. 107, 161–164 (1992).
Yang, R. et al. Coordination of histamine H3 receptor antagonists with human adrenal cytochrome P450 enzymes. Pharmacology 66, 128–135 (2002).
Ganellin, C. R. et al. Synthesis of potent non-imidazole histamine H3-receptor antagonists. Arch. Pharm. (Weinheim), 331, 395–404 (1998). Systematic modification of lead structures leading to the first non-imidazole H 3 receptor antagonists.
Menge, W. M. et al. Synthesis and biological evaluation of a novel class of non-imidazole histamine H3 antagonists. 15th EFMC Int. Symp. Med. Chem. (1998).
Meier, G. et al. Piperidino-hydrocarbon compounds as novel non-imidazole histamine H3-receptor antagonists. Bioorg. Med. Chem. 10, 2535–2542 (2002).
Faghih, R. et al. Structure–activity relationships of A-331440: a new histamine-3 antagonist with anti-obesity properties. Inflamm. Res. 53 (Suppl. 1), S79–S80 (2004).
Cowart, M. et al. A new class of potent non-imidazole H3 antagonists: 2-aminoethylbenzofurans. Bioorg. Med. Chem. Lett. 14, 689–693 (2004).
Cowart, M. et al. The medicinal chemistry of novel H3 antagonists. Inflamm. Res. 53 (Suppl. 1), S69–S70 (2004).
Pharmaceutical Research and Manufacturers of America [online], <http://www.phrma.org> (2004).
Cowart, M. et al. Achievement of behavioral efficacy and improved potency in new heterocyclic analogs of benzofuran H3 antagonists. XXXIII Ann. Meet. Eur. Histamine Res. Soc. Abs. P34 (2004).
Apodaca, R. et al. A new class of diamine-based human histamine H3 receptor antagonists: 4-(aminoalkoxy) benzylamines. J. Med. Chem. 46, 3938–3944 (2003).
Carruthers, N. I. (1-[4-(3-Piperidin-1-ylpropoxy)benzyl] piperidine): a template for the design of potent and selective non-imidazole histamine H3 receptor antagonists. XXXIII Ann. Meet. Eur. Histamine Res. Soc. Abs. P31 (2004).
Zaragoza, F. et al. 1-alkyl-4-acylpiperazines as a new class of imidazole-free histamine H3 receptor antagonists. J. Med. Chem. 47, 2833–2838 (2004).
McLeod, R. L. et al. Pharmacological characterization of the novel histamine H3-receptor antagonist N-(3,5-dichlorophenyl)-N′-[[4-(1H-imidazol-4-ylmethyl)phenyl]-methyl]-urea (SCH 79687). J. Pharmacol. Exp. Ther. 305, 1037–1044 (2003).
Varty, L. M. et al. Activation of histamine H3 receptors in human nasal mucosa inhibits sympathetic vasoconstriction. Eur. J. Pharmacol. 484, 83–89 (2004).
McLeod, R. L. et al. Combined histamine H1 and H3 receptor blockade produces nasal decongestion in an experimental model of nasal congestion. Am. J. Rhinol. 13, 391–399 (1999).
Mokdad, A. H. et al. Prevalence of obesity, diabetes, and obesity-related health risk factors, 2001. JAMA 289, 76–79 (2003).
Sakata, T. & Yoshimatsu, H. Homeostatic maintenance regulated by hypothalamic neuronal histamine. Methods Find. Exp. Clin. Pharmacol. 17 (Suppl. C), 51–56 (1995).
Kroeze, W. K. et al. H1-histamine receptor affinity predicts short-term weight gain for typical and atypical antipsychotic drugs. Neuropsychopharmacology 28, 519–526 (2003).
Karlstedt, K. et al. Expression of the H3 receptor in the developing CNS and brown fat suggests novel roles for histamine. Mol. Cell Neurosci. 24, 614–622 (2003).
Mochizuki, T. et al. In vivo release of neuronal histamine in the hypothalamus of rats measured by microdialysis. Naunyn Schmiedebergs Arch. Pharmacol. 343, 190–195 (1991).
Sindelar, D. K. et al. Central H3R activation by thioperamide does not affect energy balance. Pharmacol. Biochem. Behav. 78, 275–283 (2004).
Hancock, A. A. et al. In vitro optimization of structure activity relationships of analogues of A-331440 combining radioligand receptor binding assays and micronucleus assays of potential antiobesity histamine H3 receptor antagonists. Basic Clin. Pharmacol. Toxicol. 95, 144–152 (2004).
Rimvall, K. Effects of novel histamine H3 receptor antagonists on food intake and body weight in rodents and in larger species. Exper. Biol. 2004. (2004).
Kay, G. G. The effects of antihistamines on cognition and performance. J. Allergy Clin. Immunol. 105, S622–S627 (2000).
Tashiro, M. et al. Roles of histamine in regulation of arousal and cognition: functional neuroimaging of histamine H1 receptors in human brain. Life Sci. 72, 409–414 (2002).
Fox, G. B. et al. Two novel and selective nonimidazole H3 receptor antagonists A-304121 and A-317920: II. In vivo behavioral and neurophysiological characterization. J. Pharmacol. Exp. Ther. 305, 897–908 (2003).
Ishizuka, T. et al. Modafinil increases histamine release in the anterior hypothalamus of rats. Neurosci. Lett. 339, 143–146 (2003).
Tedford, C. E. et al. Effects of a novel, selective and potent histamine H3 receptor antagonist, GT-2331, on rat sleep-wakefulness and canine cataplexy. Soc. Neurosci. Abstr. 26, 460.3. (2000)
Hancock, A. A. & Fox, G. B. in Milestones in Drug Therapy (ed. Buccafusco, J. J.). (Birkhäuser, Basel, 2003).
Passani, M. B. et al. Central histaminergic system and cognition. Neurosci. Biobehav. Rev. 24, 107–113 (2000).
Mochizuki, T. et al. Histaminergic modulation of hippocampal acetylcholine release in vivo. J. Neurochem. 62, 2275–2282 (1994).
Giovannini, M. G. et al. Effects of histamine H3 receptor agonists and antagonists on cognitive performance and scopolamine-induced amnesia. Behav. Brain Res. 104, 147–155 (1999).
Meguro, K. et al. Effects of thioperamide, a histamine H3 antagonist, on the step-through passive avoidance response and histidine decarboxylase activity in senescence-accelerated mice. Pharmacol. Biochem. Behav. 50, 321–325 (1995).
Prast, H., Argyriou, A. & Philippu, A. Histaminergic neurons facilitate social memory in rats. Brain Res. 734, 316–318 (1996).
Fox, G. B. et al. Effects of histamine H3 receptor ligands GT-2331 and ciproxifan in a repeated acquisition avoidance response in the spontaneously hypertensive rat pup. Behav. Brain Res. 131, 151–161 (2002).
Fox, G. B. et al. Cognition enhancing effects of novel H3 receptor (H3R) antagonists in several animal models. Inflamm. Res. 53 (Suppl. 1), S49–S50 (2004).
Esbenshade, T. A. et al. ABT-239, a novel, selective, and potent human histamine H3 receptor antagonist with cognition enhancing properties. Exp. Biol. 2004. Abstr. 396.2 (2004).
Medhurst, A. D. & Wilson, D. M. Pre-clinical evaluation of novel H3 receptor antagonists. XXXIII Ann. Meet. Eur. Histamine Res. Soc. Abstr. P83 (2004).
Yates, S. L. et al. Inverse agonists of the histamine-3 receptor as appetite suppressants. Abstr. Amer. Chem. Soc. 255, MEDI2 (2003).
Seifert, R. & Wenzel-Seifert, K. Constitutive activity of G-protein-coupled receptors: cause of disease and common property of wild-type receptors. Naunyn Schmiedebergs Arch. Pharmacol. 366, 381–416 (2002).
Milligan, G., Bond, R. A. & Lee, M. Inverse agonism: pharmacological curiosity or potential therapeutic strategy? Trends Pharmacol. Sci. 16, 10–13 (1995).
Leff, P. The two-state model of receptor activation. Trends Pharmacol. Sci. 16, 89–97 (1995).
Kitbunnadaj, R. et al. Synthesis and structure-activity relationships of conformationally constrained histamine H3 receptor agonists. J. Med. Chem. 46, 5445–5457 (2003).
Leurs, R. et al. Agonist-independent regulation of constitutively active G-protein-coupled receptors. Trends Biochem. Sci. 23, 418–422 (1998).
Milligan, G. & Bond, R. A. Inverse agonism and the regulation of receptor number. Trends Pharmacol. Sci. 18, 468–474 (1997).
Yates, S. L. et al. Cloning and expression of novel isoforms of the human histamine H3 receptor. Soc. Neurosci. Abstr. 27, 804.3 (2001).
Gallagher, M. & Yates, S. L. Histamine H3 receptor polynucleotides. WO Patent o3/042359A2 (2004).
Tsui, P., Human histamine H3 gene variant-1. WO Patent 01/68665A1 (2001).
Tsui, P., Human histamine H3 gene variant-2. WO Patent 6355452B1. (2002).
Tsui, P., Human histamine H3 gene variant-3. WO Patent 01/68816A1. (2001).
Acknowledgements
The authors would like to thank N. Carruthers (Johnson & Johnson PRD), S. Celanire (UCB Pharma), A. Hancock (Abbott Laboratories), K. Rimvall (Novo Nordisk) and H. Stark (Johann Wolfgang Goethe-University Frankfurt) for helpful discussions and sharing information before publication.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Competing interests
The authors act or have acted as consultants for various pharmaceutical companies active in the field of histamine receptors and have also received research payments from some companies in this field.
Related links
Related links
DATABASES
Entrez Gene
OMIM
Glossary
- PRODRUG
-
A pharmacologically inactive compound that is converted to the active form of the drug by endogenous enzymes or metabolism. It is generally designed to overcome problems associated with stability, toxicity, lack of specificity or limited (oral) bioavailability.
- PARTIAL AGONIST
-
Whereas a full agonist produces the system maximal response, a partial agonist produces a maximal response that is below that of the system maximum (and that of a full agonist). As well as producing a sub-maximal response, partial agonists antagonise full agonists.
- HYPOTHALAMUS
-
The hypothalamus is the region of the brain that controls body temperature, hunger and thirst, and circadian cycles.
- INVERSE AGONIST
-
Inverse agonists reverse constitutive receptor activity, and are proposed to show selectively higher affinity for the inactive versus the active conformation of the receptor. In the absence of constitutive activity, inverse agonists function as competitive antagonists.
- PHARMACOPHORE
-
The ensemble of steric and electronic features that is necessary to ensure optimal interactions with a specific biological target structure and to trigger (or to block) its biological response.
- NARCOLEPSY
-
Narcolepsy is a neurological disorder of sleep regulation that affects the control of sleep and wakefulness. The four classic symptoms are excessive daytime sleepiness, cataplexy, sleep paralysis and hypnagogic hallucinations.
Rights and permissions
About this article
Cite this article
Leurs, R., Bakker, R., Timmerman, H. et al. The histamine H3 receptor: from gene cloning to H3 receptor drugs. Nat Rev Drug Discov 4, 107–120 (2005). https://doi.org/10.1038/nrd1631
Published:
Issue Date:
DOI: https://doi.org/10.1038/nrd1631
This article is cited by
-
P19-derived neuronal cells express H1, H2, and H3 histamine receptors: a biopharmaceutical approach to evaluate antihistamine agents
Amino Acids (2023)
-
Safety, Tolerability, and Pharmacokinetics of SUVN-G3031, a Novel Histamine-3 Receptor Inverse Agonist for the Treatment of Narcolepsy, in Healthy Human Subjects Following Single and Multiple Oral Doses
Clinical Drug Investigation (2020)
-
Connection between gut microbiome and the development of obesity
European Journal of Clinical Microbiology & Infectious Diseases (2019)
-
Local tissue manipulation via a force- and pressure-controlled AFM micropipette for analysis of cellular processes
Scientific Reports (2018)
-
Gut microbiome production of short-chain fatty acids and obesity in children
European Journal of Clinical Microbiology & Infectious Diseases (2018)