Neuroprotective activity of new Δ3-N-acylethanolamines in a focal ischemia stroke model.

N-acylethanolamines (NAE, also called ethanolamides) are significant lipid signaling molecules with anti-inflammatory, pain-relieving, cell-protective, and anticancer properties. Here, we present the use of a hitherto unreported group of Δ3-NAE and also some Δ4- and Δ5-NAE, in in vitro and in vivo assays to gain a better understanding of their structure-bioactivity relationships. We have developed an efficient synthetic method to rapidly produce novel unlabeled and 13 C-labeled Δ3-NAE (NAE-18:5n-3, NAE-18:4n-6) and Δ4-NAE (NAE-22:5n-6). The new NAE with shorter carbon backbone structures confers greater neuroprotection than their longer carbon backbone counterparts, including anandamide (Δ5-NAE-20:4n-6) in a focal ischemia mouse model of stroke. This study highlights structure-dependent protective effects of new NAE following focal ischemia, in which some of the new NAE, administered intranasally, lead to significantly reduced infarct volume and improved recovery of limb use. The relative affinity of the new NAE toward cannabinoid receptors was assessed against anandamide, NAE-22:6n-3 and NAE-20:5n-3, which are known cannabinoid receptor ligands with high-binding constants. Among the newly synthesized NAE, Δ4-NAE-22:5n-6 shows the greatest relative affinity to cannabinoid receptors hCB1 and hCB2 , and inhibition of cyclic adenosine monophosphate activity through hCB2 compared to anandamide.

Exploring Stereochemical and Conformational Requirements at Cannabinoid Receptors for Synthetic Cannabinoids Related to SDB-006, 5F-SDB-006, CUMYL-PICA, and 5F-CUMYL-PICA.

Synthetic cannabinoid receptor agonists (SCRAs) represent the most rapidly expanding class of new psychoactive substances (NPSs). Despite the prevalence and potency of recent chiral indole-3-carboxamide SCRAs, few pharmacological data are available regarding the enantiomeric bias of these NPSs toward human CB1 and CB2 receptors. A series of homochiral indole-3-carboxamides derived from (S)- and (R)-α-methylbenzylamine and featuring variation of the 1-alkyl substituent were prepared, pharmacologically evaluated, and compared to related achiral congeners derived from cumyl- and benzylamine. Competitive binding assays demonstrated that all analogues derived from either enantiomer of α-methylbenzylamine (14-17) showed affinities for CB1 (Ki = 47.9-813 nM) and CB2 (Ki = 47.9-347 nM) that were intermediate to that of the corresponding benzylic (10-13, CB1 Ki = 550 nM to >10 µM; CB2 Ki = 61.7 nM to >10 µM) and cumyl derivatives (6-9, CB1 Ki = 12.6-21.4 nM; CB2 Ki = 2.95-24.5 nM). In a fluorometric membrane potential assay, all α-methylbenzyl analogues (excluding 17) were potent, efficacious agonists of CB1 (EC50 = 32-464 nM; Emax = 89-104%) and low efficacy agonists of CB2 (EC50 = 54-500 nM; Emax = 52-77%), with comparable or greater potency than the benzyl analogues and much lower potency than the cumyl derivatives, consistent with binding trends. The relatively greater affinity and potency of (S)-14-17 compared to (R)-14-17 analogues at CB1 highlighted an enantiomeric bias for this series of SCRAs. Molecular dynamics simulations provided a conformational basis for the observed differences in agonist potency at CB1 pending benzylic substitution.

Divalent cannabinoid-1 receptor ligands: A linker attachment point survey of SR141716A for development of high-affinity CB1R molecular probes.

The cannabinoid-1 receptor (CB1R) inverse agonist SR141716A has proven useful for study of the endocannabinoid system, including development of divalent CB1R ligands possessing a second functional motif attached via a linker unit. These have predominantly employed the C3 position of the central pyrazole ring for linker attachment. Despite this precedent, a novel series of C3-linked CB1R-D2R divalent ligands exhibited extremely high affinity at the D2R, but only poor affinity for the CB1R. A systematic linker attachment point survey of the SR141716A pharmacophore was therefore undertaken, establishing the C5 position as the optimal site for linker conjugation. This linker attachment survey enabled the identification of a novel divalent ligand as a lead compound to inform ongoing development of high-affinity CB1R molecular probes.

Do Toxic Synthetic Cannabinoid Receptor Agonists Have Signature in Vitro Activity Profiles? A Case Study of AMB-FUBINACA.

Recreational consumption of synthetic cannabinoid receptor agonists (SCRAs) is a growing crisis in public health in many parts of the world. AMB-FUBINACA is a member of this class of drugs and is responsible for a large proportion of SCRA-related toxicity both in New Zealand and internationally. Strikingly, little is currently known about the mechanisms by which SCRAs exert toxic effects or whether their activity through the CB1 cannabinoid receptor (the mediator of cannabinoid-related psychoactivity) is sufficient to explain clinical observations. The current study therefore set out to perform a basic molecular pharmacology characterization of AMB-FUBINACA (in comparison to traditional research cannabinoids CP55,940, WIN55,212-2, and Δ9-THC) in fundamental pathways of receptor activity, including cAMP inhibition, pERK activation, ability to drive CB1 internalization, and ability to induce translocation of ß-arrestins-1 and -2. Activity pathways were then compared by operational analysis to indicate whether AMB-FUBINACA may be a biased ligand. Results revealed that AMB-FUBINACA is highly efficacious and potent in all pathways assayed. However, surprisingly, bias analysis suggested that Δ9-THC, not AMB-FUBINACA, may be a biased ligand, with it being less active in both arrestin pathways than predicted by the activity of the other ligands tested. These data may help predict molecular characteristics of SCRAs. However, more research is required to determine whether these molecular effects manifest in toxicity at tissue/system level.

The chemistry and pharmacology of putative synthetic cannabinoid receptor agonist (SCRA) new psychoactive substances (NPS) 5F-PY-PICA, 5F-PY-PINACA, and their analogs.

5F-PY-PICA and 5F-PY-PINACA are pyrrolidinyl 1-(5-fluoropentyl)ind (az)ole-3-carboxamides identified in 2015 as putative synthetic cannabinoid receptor agonist (SCRA) new psychoactive substances (NPS). 5F-PY-PICA, 5F-PY-PINACA, and analogs featuring variation of the 1-alkyl substituent or contraction, expansion, or scission of the pyrrolidine ring were synthesized and characterized by nuclear magnetic resonance (NMR) spectroscopy and liquid chromatography-quadrupole time-of-flight-mass spectrometry (LC-QTOF-MS). In competitive binding experiments against HEK293 cells expressing human cannabinoid receptor type 1 (hCB1 ) or type 2 (hCB2 ), all analogs showed minimal affinity for CB1 (pKi  < 5), although several demonstrated moderate CB2 binding (pKi 5.45-6.99). In fluorescence-based membrane potential assays using AtT20-hCB1 or -hCB2 cells, none of the compounds (at 10 µM) produced an effect >50% of the classical cannabinoid agonist CP55,940 (at 1 µM) at hCB1 , although several showed slightly higher relative efficacy at hCB2 . Expansion of the pyrrolidine ring of 5F-PY-PICA to an azepane (8) conferred the greatest hCB2 affinity (pKi 6.99) and activity (pEC50 7.54, Emax 72%) within the series. Unlike other SCRA NPS evaluated in vivo using radio biotelemetry, 5F-PY-PICA and 5F-PY-PINACA did not produce cannabimimetic effects (hypothermia, bradycardia) in mice at doses up to 10 mg/kg.

Chromenopyrazole-based High Affinity, Selective Fluorescent Ligands for Cannabinoid Type 2 Receptor.

Cannabinoid type 2 receptor (CB2R) is an attractive target for the treatment of pain and inflammatory disorders. Availability of a selective CB2R fluorescent ligand to study CB2R expression and localization in healthy and disease conditions would greatly contribute to improving our understanding of this receptor. Herein, we report a series of chromenopyrazole-based CB2R fluorescent ligands. The highest affinity fluorescent ligand was Cy5-containing 24 (hCB2R pK i = 7.38 ± 0.05), which had 131-fold selectivity over CB1R. In a cAMP BRET assay, 24 behaved as a potent CB2R inverse agonist. Widefield imaging experiments showed that 24 binds to CB2R in live cells with good selectivity and low levels of nonspecific fluorescence. The high affinity, selectivity, and suitable imaging properties of fluorescent ligand 24 make it a valuable tool for studying CB2R.

Synthesis and pharmacology of new psychoactive substance 5F-CUMYL-P7AICA, a scaffold- hopping analog of synthetic cannabinoid receptor agonists 5F-CUMYL-PICA and 5F-CUMYL-PINACA.

Synthetic cannabinoid receptor agonists (SCRAs) are a dynamic class of new psychoactive substances (NPS), with novel chemotypes emerging each year. Following the putative detection of 5F-CUMYL-P7AICA in Australia in 2016, the scaffold-hopping SCRAs 5F-CUMYL-PICA, 5F-CUMYL-PINACA, and 5F-CUMYL-P7AICA were synthesized and characterized by nuclear magnetic resonance (NMR) spectroscopy, gas chromatography-mass spectrometry (GC-MS), and liquid chromatography-quadrupole time-of-flight-MS (LC-QTOF-MS). Since little is known of the pharmacology of 7-azaindole SCRAs like 5F-CUMYL-P7AICA, the binding affinities and functional activities of all compounds at cannabinoid type 1 and type 2 receptors (CB1 and CB2 , respectively) were assessed using tritiated radioligand competition experiments and fluorescence-based plate reader membrane potential assays. Despite CB1 binding affinities differing by over two orders of magnitude (Ki  = 2.95-174 nM), all compounds were potent and efficacious CB1 agonists (EC50  = 0.43-4.7 nM), with consistent rank order for binding and functional activity (5F-CUMYL-PINACA >5F-CUMYL-PICA >5F-CUMYL-P7AICA). Additionally, 5F-CUMYL-P7AICA was found to exert potent cannabimimetic effects in mice, inducing hypothermia (6°C, 3 mg/kg) through a CB1 -dependent mechanism.

Alkyl indole-based cannabinoid type 2 receptor tools: Exploration of linker and fluorophore attachment.

Cannabinoid type 2 (CB2) receptor continues to emerge as a promising drug target for many diseases and conditions. New tools for studying CB2 receptor are required to further inform how this receptor functions in healthy and diseased states. The alkyl indole scaffold is a well-recognised ligand for cannabinoid receptors, and in this study the indole C5-7 positions were explored for linker and fluorophore attachment. A new high affinity, CB2 receptor selective inverse agonist was identified (16b) along with a general trend of C5-substituted indoles acting as agonists versus C7-substituted indoles acting as inverse agonists. The indole C7 position was found to be the most tolerant to linker extension and resulted in a high affinity inverse agonist with a medium length linker (19). Although a high affinity fluorescent ligand for CB2 receptor was not identified in this study, the indole C7 position shows great promise for fluorophore or probe attachment.

Affinity and Efficacy Studies of Tetrahydrocannabinolic Acid A at Cannabinoid Receptor Types One and Two.

Introduction:Cannabis biosynthesizes Δ9-tetrahydrocannabinolic acid (THCA-A), which decarboxylates into Δ9-tetrahydrocannabinol (THC). There is growing interest in the therapeutic use of THCA-A, but its clinical application may be hampered by instability. THCA-A lacks cannabimimetic effects; we hypothesize that it has little binding affinity at cannabinoid receptor 1 (CB1). Materials and Methods: Purity of certified reference standards were tested with high performance liquid chromatography (HPLC). Binding affinity of THCA-A and THC at human (h) CB1 and hCB2 was measured in competition binding assays, using transfected HEK cells and [3H]CP55,940. Efficacy at hCB1 and hCB2 was measured in a cyclic adenosine monophosphase (cAMP) assay, using a Bioluminescence Resonance Energy Transfer (BRET) biosensor. Results: The THCA-A reagent contained 2% THC. THCA-A displayed small but measurable binding at both hCB1 and hCB2, equating to approximate Ki values of 3.1µM and 12.5µM, respectively. THC showed 62-fold greater affinity at hCB1 and 125-fold greater affinity at hCB2. In efficacy tests, THCA-A (10µM) slightly inhibited forskolin-stimulated cAMP at hCB1, suggestive of weak agonist activity, and no measurable efficacy at hCB2. Discussion: The presence of THC in our THCA-A certified standard agrees with decarboxylation kinetics (literature reviewed herein), which indicate contamination with THC is nearly unavoidable. THCA-A binding at 10µM approximated THC binding at 200nM. We therefore suspect some of our THCA-A binding curve was artifact-from its inevitable decarboxylation into THC-and the binding affinity of THCA-A is even weaker than our estimated values. We conclude that THCA-A has little affinity or efficacy at CB1 or CB2.

Real-Time Measurement of Cannabinoid Receptor-Mediated cAMP Signaling.

Cannabinoid receptors, like other GPCRs, signal via a spectrum of related signaling pathways. Recently, monitoring GPCR-mediated cAMP signaling has become significantly easier with the development of genetically encoded, transfectable cAMP biosensors. Cell lines transfected with these biosensors can be monitored continuously, allowing the analysis of receptor-mediated signaling in unprecedented detail. Here, we describe a protocol for transfectable biosensors which report cellular cAMP concentrations by bioluminescence resonance energy transfer (BRET). This assay system has been utilized to elucidate the temporal nature of agonists and allosteric modulators of the cannabinoid receptor CB1. In particular, the CB1 allosteric modulator ORG27569 has been shown to modify receptor agonism in a time-dependent fashion; a characteristic which would not have been observed via traditional endpoint methods of detecting cAMP signaling. BRET cAMP biosensors are suitable for miniaturization and automation, and as such are valuable and cost-effective tools for moderate- to high-throughput experimental protocols.

Cannabinoid CB2 receptor ligand profiling reveals biased signalling and off-target activity.

The cannabinoid CB2 receptor (CB2R) represents a promising therapeutic target for various forms of tissue injury and inflammatory diseases. Although numerous compounds have been developed and widely used to target CB2R, their selectivity, molecular mode of action and pharmacokinetic properties have been poorly characterized. Here we report the most extensive characterization of the molecular pharmacology of the most widely used CB2R ligands to date. In a collaborative effort between multiple academic and industry laboratories, we identify marked differences in the ability of certain agonists to activate distinct signalling pathways and to cause off-target effects. We reach a consensus that HU910, HU308 and JWH133 are the recommended selective CB2R agonists to study the role of CB2R in biological and disease processes. We believe that our unique approach would be highly suitable for the characterization of other therapeutic targets in drug discovery research.

Application of xCELLigence RTCA Biosensor Technology for Revealing the Profile and Window of Drug Responsiveness in Real Time.

The xCELLigence technology is a real-time cellular biosensor, which measures the net adhesion of cells to high-density gold electrode arrays printed on custom-designed E-plates. The strength of cellular adhesion is influenced by a myriad of factors that include cell type, cell viability, growth, migration, spreading and proliferation. We therefore hypothesised that xCELLigence biosensor technology would provide a valuable platform for the measurement of drug responses in a multitude of different experimental, clinical or pharmacological contexts. In this manuscript, we demonstrate how xCELLigence technology has been invaluable in the identification of (1) not only if cells respond to a particular drug, but (2) the window of drug responsiveness. The latter aspect is often left to educated guess work in classical end-point assays, whereas biosensor technology reveals the temporal profile of the response in real time, which enables both acute responses and longer term responses to be profiled within the same assay. In our experience, the xCELLigence biosensor technology is suitable for highly targeted drug assessment and also low to medium throughput drug screening, which produces high content temporal data in real time.

Trefoil factor 3 (TFF3) enhances the oncogenic characteristics of prostate carcinoma cells and reduces sensitivity to ionising radiation.

Trefoil factor 3 (TFF3) is a secreted protein which functions in mucosal repair of the gastrointestinal tract. This is achieved through the combined stimulation of cell migration and prevention of apoptosis and anoikis, thus facilitating repair. Deregulated TFF3 expression at the gene and protein level is implicated in numerous cancers. In prostate cancer TFF3 has previously been reported as a potential biomarker, overexpressed in a subset of primary and metastatic cases. Here we investigated the effect of increased TFF3 expression on prostate cancer cell behaviour. Oncomine analysis demonstrated that TFF3 mRNA expression was upregulated in prostate cancer compared to normal tissue. Forced-expression models were established in the prostate cancer cell lines, DU145 and PC3, by stable transfection of an expression vector containing the TFF3 cDNA. Forced expression of TFF3 significantly increased total cell number and cell viability, cell proliferation and cell survival. In addition, TFF3 enhanced anchorage independent growth, 3-dimensional colony formation, wound healing and cell migration compared to control transfected cell lines. We also observed reduced sensitivity to ionising radiation in stably transfected cell lines. In dose response experiments, forced expression of TFF3 significantly enhanced the regrowth of PC3 cells following ionising radiation compared with control transfected cells. In addition, TFF3 enhanced clonogenic survival of DU145 and PC3 cells. These studies indicate that targeting TFF3 for the treatment of prostate cancer warrants further investigation.

Development of positive control tissue for in situ hybridisation using Alvetex scaffolds.

BACKGROUND: In situ hybridisation (ISH) is a robust method to determine the presence of mRNA for specific genes within a tissue. Ideally, positive and negative control tissues are used to determine probe specificity. However, this is not always possible, particularly for human genes where no knock-out controls exist. NEW METHOD: Here we report a novel method of growing positive control cells in a scaffold (Alvetex) to create 3D tissues suitable for sectioning with a cryostat. Sectioning slices through cells, similar to the effect on tissue and therefore provides improved penetration of the in situ riboprobes. COMPARISON TO EXISTING METHOD: ISH conducted on cells has been problematic due to the difficulty of efficient probe penetration, due to a semi-intact cell membrane, and cell preparations failing to withstand high stringency washes. Our new method circumvents this issue by enabling the positive control cells to be sectioned like a tissue. RESULTS: HEK cells transfected with the genes of interest (in this case CB1 and NeuN) grown in Alvetex and cryosectioned were utilised to validate riboprobes and establish stringency conditions. These conditions were then transferred directly to human brain sections. CONCLUSION: This method can be adapted to generate positive controls for ISH for any gene of interest. It provides a valuable option in human neuroscience where access to precious brain tissue is limited or where expression of a target gene is unknown.

Enrichment of differentiated hNT neurons and subsequent analysis using flow-cytometry and xCELLigence sensing.

BACKGROUND: Human neurons (hNT neurons), obtained from the NTera2/D1 precursor cell line, are highly valued by many neuroscientists as isolation of adult human primary neuronal cells continues to elude us. hNT neurons are generated by differentiation of the NT2 precursors for a period of 4 weeks followed by 2 weeks of mitotic inhibition. This yields a heterogeneous population of neuronal phenotypes and underlying astrocyte precursors, the latter of which are very difficult to visualise using standard light microscopy. Such a mixed culture is acceptable for some applications (e.g. measurement of synaptic plasticity), whereas others (e.g. proteomics or transcriptomics) require almost pure cultures of hNT neurons. NEW METHOD: Here we describe a simple method for obtaining highly enriched cultures of hNT neurons following the first neuronal harvest and detail several additional methods, namely flow-cytometry and xCELLigence© biosensor technology, to rapidly and reliably determine the purity and viability of the cultures. COMPARISON WITH EXISTING METHODS: This method of enrichment for the neurons is novel and advances the end user applications of the cells. RESULTS: In addition, we apply the enrichment method to conduct analysis of cell-surface markers using flow-cytometry on the enriched neuronal cells. Furthermore, we apply this method to generate enriched neuronal cells on which we conduct analysis of cell-surface markers using flow-cytometry. CONCLUSIONS: Collectively, this paper describes several new advances, which will create opportunities when using these cells and similar preparations, and provides the protocol for analysis of these cells using flow-cytometry and biosensor technology.