An invertebrate model for CNS drug discovery: Transcriptomic and functional analysis of a mammalian P-glycoprotein ortholog.

BACKGROUND: ABC efflux transporters at the blood brain barrier (BBB), namely the P-glycoprotein (P-gp), restrain the development of central nervous system (CNS) drugs. Consequently, early screening of CNS drug candidates is pivotal to identify those affected by efflux activity. Therefore, simple, high-throughput and predictive screening models are required. The grasshopper (locust) has been developed as an invertebrate in situ model for BBB permeability assessment, as it has shown similarities to vertebrate models. METHODS: Transcriptome profiling of ABC efflux transporters in the locust brain was performed. Subsequently, identified transcripts were matched with their counterparts in human, rat, mouse and Drosophila melanogaster, based on amino acid sequence similarity, and phylogenetic trees were constructed to reveal the most likely evolutionary history of the proteins. Further, functional characterization of a P-gp ortholog was achieved through transport studies, using a selective P-gp substrate and locust brain in situ, followed by kinetic analyses. RESULTS: A protein with high sequence similarity to the ABCB1 gene of vertebrates was found in the locust brain, which encodes P-gp in human and is considered the most vital efflux pump. Functionally, this model showed transport kinetic behaviors comparable to those obtained from in vitro models. Particularly, substrate affinity of the putative P-gp was observed as in P-gp expressing cells lines, used for predicting drug penetration across biological barriers. CONCLUSION: Findings suggest a conserved mechanism of brain efflux activity between insects and vertebrates, confirming that this model holds promise for inexpensive and high-throughput screening relative to in vivo models, for CNS drug discovery.

Identification of a functional homolog of the mammalian CYP3A4 in locusts.

Insects have been proposed as a new tool in early drug development. It was recently demonstrated that locusts have an efflux transporter localized in the blood-brain barrier (BBB) that is functionally similar to the mammalian P-glycoprotein efflux transporter. Two insect BBB models have been put forward, an ex vivo model and an in vivo model. To use the in vivo model it is necessary to fully characterize the locust as an entire organism with regards to metabolic pathways and excretion rate. In the present study, we have characterized the locust metabolism of terfenadine, a compound that in humans is specific to the cytochrome P450 enzyme 3A4. Using high-resolution mass spectrometry coupled to ultra-high-performance liquid chromatography, we have detected metabolites identical to human metabolites of terfenadine. The formation of human metabolites in locusts was inhibited by ketoconazole, a mammalian CYP3A4 inhibitor, suggesting that the enzyme responsible for the human metabolite formation in locusts is functionally similar to human CYP3A4. Besides the human metabolites of terfenadine, additional metabolites were formed in locusts. These were tentatively identified as phosphate and glucose conjugates. In conclusion, not only may locusts be a model useful for determining BBB permeation, but possibly insects could be used in metabolism investigation. However, extensive characterization of the insect model is necessary to determine its applicability.

The grasshopper: a novel model for assessing vertebrate brain uptake.

The aim of the present study was to develop a blood-brain barrier (BBB) permeability model that is applicable in the drug discovery phase. The BBB ensures proper neural function, but it restricts many drugs from entering the brain, and this complicates the development of new drugs against central nervous system diseases. Many in vitro models have been developed to predict BBB permeability, but the permeability characteristics of the human BBB are notoriously complex and hard to predict. Consequently, one single suitable BBB permeability screening model, which is generally applicable in the early drug discovery phase, does not yet exist. A new refined ex vivo insect-based BBB screening model that uses an intact, viable whole brain under controlled in vitro-like exposure conditions is presented. This model uses intact brains from desert locusts, which are placed in a well containing the compound solubilized in an insect buffer. After a limited time, the brain is removed and the compound concentration in the brain is measured by conventional liquid chromatography-mass spectrometry. The data presented here include 25 known drugs, and the data show that the ex vivo insect model can be used to measure the brain uptake over the hemolymph-brain barrier of drugs and that the brain uptake shows linear correlation with in situ perfusion data obtained in vertebrates. Moreover, this study shows that the insect ex vivo model is able to identify P-glycoprotein (Pgp) substrates, and the model allows differentiation between low-permeability compounds and compounds that are Pgp substrates.

Exploring SAR features in diverse library of 4-cyanomethyl-pyrazole-3-carboxamides suitable for further elaborations as CB1 antagonists.

A chemically diverse library of secondary and tertiary 4-cyanomethyl-1,5-diphenyl-1H-pyrazole-3-carboxamides was synthesized to enable mapping of the SAR, in the eastern amide region, with regard to CB1 antagonist activity, This study was initiated as a prelude to the design and synthesis of possible CB1 antagonists that do not readily pass the blood-brain-barrier. In general a range of modifications were found to be tolerated in this part of the molecule, although polar and especially charged groups did to a degree reduce the CB1 antagonistic activity. Several compounds with single-digit or even sub-nanomolar potency, suitable for further elaboration of the nitrile moiety, were identified.

Conversion of 4-cyanomethyl-pyrazole-3-carboxamides into CB1 antagonists with lowered propensity to pass the blood-brain-barrier.

A series of amides, amidines and amidoximes have been made from the corresponding nitrile compounds, to provide potent antagonists and inverse agonists for the CB1 receptor with considerably lower lipophiliciy, higher polar surface area and improved plasma/brain ratios compared to the centrally acting rimonabant. Extensive investigations of ADME and in vivo pharmacological properties led to selection of the amide series and specifically the 4-(4-fluorophenyl)piperidin-4-ol derivative D4. A clear improvement in the peripheral profile over rimonabant was seen, although some contribution of central effect on the pronounced weight reduction in obese mice cannot be ruled out.

Exploration of SAR features by modifications of thiazoleacetic acids as CRTH2 antagonists.

The SAR features have been further explored for (2-benzhydryl-4-phenyl-thiazol-5-yl)acetic acids as CRTH2 (chemoattractant receptor-homologous molecule expressed on Th2 cells) antagonists. The introduction of a nitrogen or a methyl substituent in the benzhydrylic position offer two alternative drugable scaffolds attractive for unsymmetrically substituted derivatives. An imidazole analogue lacks activity due to formation of a favored coplanar intramolecular hydrogen bond. The pyrimidine derivative 18 represents a potent and selective compound that will be subject to continued investigations.

Characterization of a novel brain barrier ex vivo insect-based P-glycoprotein screening model.

In earlier studies insects were proposed as suitable models for vertebrate blood-brain barrier (BBB) permeability prediction and useful in early drug discovery. Here we provide transcriptome and functional data demonstrating the presence of a P-glycoprotein (Pgp) efflux transporter in the brain barrier of the desert locust (Schistocerca gregaria). In an in vivo study on the locust, we found an increased uptake of the two well-known Pgp substrates, rhodamine 123 and loperamide after co-administration with the Pgp inhibitors cyclosporine A or verapamil. Furthermore, ex vivo studies on isolated locust brains demonstrated differences in permeation of high and low permeability compounds. The vertebrate Pgp inhibitor verapamil did not affect the uptake of passively diffusing compounds but significantly increased the brain uptake of Pgp substrates in the ex vivo model. In addition, studies at 2°C and 30°C showed differences in brain uptake between Pgp-effluxed and passively diffusing compounds. The transcriptome data show a high degree of sequence identity of the locust Pgp transporter protein sequences to the human Pgp sequence (37%), as well as the presence of conserved domains. As in vertebrates, the locust brain-barrier function is morphologically confined to one specific cell layer and by using a whole-brain ex vivo drug exposure technique our locust model may retain the major cues that maintain and modulate the physiological function of the brain barrier. We show that the locust model has the potential to act as a robust and convenient model for assessing BBB permeability in early drug discovery.

Models for predicting blood-brain barrier permeation.

The endothelial blood-brain barrier (BBB) ensures an optimal environment for proper neural function in vertebrates; however, it also creates a major obstacle for the medical treatment of brain diseases. Despite significant progress in the development of various in vitro and in silico models for predicting BBB permeation, many challenges remain and, so far, no model is able to meet the early drug discovery demands of the industry for reliability and time and cost efficiency. Recently, it was found that the grasshopper (Locusta migratoria) brain barrier has similar functionality as the vertebrate BBB. The insect model can thus be used as a surrogate for the vertebrate BBB as it meets the demands required during the drug discovery phase.