Willard J. Costain

Brain penetration, target engagement, and disposition of the blood–brain barrier-crossing bispecific antibody antagonist of metabotropic glutamate receptor type 1

Receptor mediated transcytosis harnessing the cellular uptake and transport of natural ligands across the blood‐brain barrier (BBB) has been identified as a means for antibody delivery to the CNS. In this study, we characterized bispecific antibodies in which a BBB‐crossing antibody fragment FC5 was used as a BBB carrier. Cargo antibodies were either a high‐affinity, selective antibody antagonist of the metabotropic glutamate receptor‐1 (BBB‐mGluR1), a widely abundant CNS target, or an IgG that does not bind the CNS target (BBB‐NiP). Both BBB‐NiP and BBB‐mGluR1 demonstrated a similar 20‐fold enhanced rate of transcytosis across an in vitro BBB model compared with mGluR1 IgG fused to a control antibody fragment. All 3 bispecific antibodies exhibited identical pharmacokinetics in vivo. Comparative assessment of BBB‐NiP and BBB‐mGluR1 revealed that, whereas their serum pharmacokinetics and BBB penetration were identical, their central disposition (brain levels) and elimination (cerebrospinal fluid levels) were widely different, due to central target‐mediated removal of the mGluR1‐engaging antibody. Central mGluR1 target engagement after systemic administration was demonstrated by a dose‐dependent inhibition of mGluR‐1‐mediated thermal hyperalgesia and by colocalization of the antibody with thalamic neurons involved inmGluR1‐mediated pain processing. We demonstrate the feasibility of targeting central G‐protein‐coupled receptors using a BBB‐crossing bispecific antibody approach and emerging principles that govern brain distribution and disposition of these antibodies. These data will be important for designing safe and selective CNS antibody therapeutics.—Webster, C. I., Caram‐Salas, N., Haqqani, A. S., Thom, G., Brown, L., Rennie, K., Yogi, A., Costain, W., Brunette, E., Stanimirovic, D. B. Brain penetration, target engagement, and disposition of the blood‐brain barrier‐crossing bispecific antibody antagonist of metabotropic glutamate receptor type 1 FASEB J. 30, 1927–1940 (2016). www.fasebj.org

Cerebral ischemia causes dysregulation of synaptic adhesion in mouse synaptosomes

Synaptic pathology is observed during hypoxic events in the central nervous system in the form of altered dendrite structure and conductance changes. These alterations are rapidly reversible, on the return of normoxia, but are thought to initiate subsequent neuronal cell death. To characterize the effects of hypoxia on regulators of synaptic stability, we examined the temporal expression of cell adhesion molecules (CAMs) in synaptosomes after transient middle cerebral artery occlusion (MCAO) in mice. We focused on events preceding the onset of ischemic neuronal cell death (< 48 h). Synaptosome preparations were enriched in synaptically localized proteins and were free of endoplasmic reticulum and nuclear contamination. Electron microscopy showed that the synaptosome preparation was enriched in spheres (≈650 nm in diameter) containing secretory vesicles and postsynaptic densities. Forebrain mRNA levels of synaptically located CAMs was unaffected at 3 h after MCAO. This is contrasted by the observation of consistent downregulation of synaptic CAMs at 20 h after MCAO. Examination of synaptosomal CAM protein content indicated that certain adhesion molecules were decreased as early as 3 h after MCAO. For comparison, synaptosomal Agrn protein levels were unaffected by cerebral ischemia. Furthermore, a marked increase in the levels of p-Ctnnb1 in ischemic synaptosomes was observed. p-Ctnnb1 was detected in hippocampal fiber tracts and in cornu ammonis 1 neuronal nuclei. These results indicate that ischemia induces a dysregulation of a subset of synaptic proteins that are important regulators of synaptic plasticity before the onset of ischemic neuronal cell death.

Proteomic analysis of synaptosomal protein expression reveals that cerebral ischemia alters lysosomal Psap processing.

Cerebral ischemia (CI) induces dramatic changes in synaptic structure and function that precedes delayed post‐ischemic neuronal death. Here, a proteomic analysis was used to identify the effects of focal CI on synaptosomal protein levels. Contralateral and ipsilateral synaptosomes, prepared from adult mice subjected to 60 min middle cerebral artery occlusion, were isolated following 3, 6 and 20 h of reperfusion. Synaptosomal protein samples (n=3) were labeled using the cleavable ICAT™ system prior to analysis with nanoLC‐MS/MS. Each sample was analyzed by LC‐MS to identify differential expressions using InDEPT software and differentially expressed peptides were identified by targeted LC‐MS/MS. A total of 62 differentially expressed proteins were identified and Gene Ontology classification (cellular component) indicated that the majority of the proteins were located in the mitochondria and other components consistent with synaptic localization. The observed alterations in synaptic protein levels poorly correlated with gene expression, indicating the involvement of post‐transcriptional regulatory mechanisms in determining post‐ischemic synaptic protein content. Additionally, immunohistochemistry analysis of prosaposin (Psap) and saposin C (SapC) indicates that CI disrupts Psap processing and glycosphingolipid metabolism. These results demonstrate that the synapse is adversely affected by CI and may play a role in mediating post‐ischemic neuronal viability.

Pharmacological characterization of emerging synthetic cannabinoids in HEK293T cells and hippocampal neurons.

There has been a worldwide proliferation of synthetic cannabinoids that have become marketed as legal alternatives to cannabis (marijuana). Unfortunately, there is a dearth of information about the pharmacological effects of many of these emerging synthetic cannabinoids (ESCs), which presents a challenge for regulatory authorities that need to take such scientific evidence into consideration in order to regulate ECSs as controlled substances. We aimed to characterize the pharmacological properties of ten ESCs using two cell based assays that enabled the determination of potency and efficacy relative to a panel of well-characterized cannabinoids. Agonist-mediated inhibition of forskolin-stimulated cyclic adenosine monophosphate (cAMP) levels was monitored in live HEK293T cells transfected with human cannabinoid receptor 1 gene (CNR1) and pGloSensor-22F. Pharmacological analysis of this data indicated that all of the ESCs tested were full agonists, with the following rank order of potency: Win 55212-2≈5F-PB-22≈AB-PINACA≈EAM-2201≈MAM-2201>JWH-250≈ PB-22>AKB48 N-(5FP)>AKB-48≈STS-135>XLR-11. Assessment of agonist-stimulated depression of Ca(2+) transients was also used to confirm the efficacy of five ESCs (XLR-11, JWH-250, AB-PINACA, 5F-PB-22, and MAM-2201) in cultured primary hippocampal neurons. This work aims to help inform decisions made by regulatory agencies concerned with the profusion of these poorly characterized recreational drugs.

Effect of synthetic cannabinoids on spontaneous neuronal activity: Evaluation using Ca(2+) spiking and multi-electrode arrays.

Activation of cannabinoid receptor 1 (CB1) inhibits synaptic transmission in hippocampal neurons. The goal of this study was to evaluate the ability of benchmark and emerging synthetic cannabinoids to suppress neuronal activity in vitro using two complementary techniques, Ca(2+) spiking and multi-electrode arrays (MEAs). Neuron culture and fluorescence imaging conditions were extensively optimized to provide maximum sensitivity for detection of suppression of neural activity by cannabinoids. The neuronal Ca(2+) spiking frequency was significantly suppressed within 10min by the prototypic aminoalkylindole cannabinoid, WIN 55,212-2 (10µM). Suppression by WIN 55,212-2 was not improved by pharmacological intervention with signaling pathways known to interfere with CB1 signaling. The naphthoylindole CB1 agonist, JWH-018 suppressed Ca(2+) spiking at a lower concentration (2.5µM), and the CB1 antagonist rimonabant (5µM), reversed this suppression. In the MEA assay, the ability of synthetic CB1 agonists to suppress spontaneous electrical activity of hippocampal neurons was evaluated over 80min sessions. All benchmark (WIN 55,212-2, HU-210, CP 55,940 and JWH-018) and emerging synthetic cannabinoids (XLR-11, JWH-250, 5F-PB-22, AB-PINACA and MAM-2201) suppressed neural activity at a concentration of 10µM; furthermore, several of these compounds also significantly suppressed activity at 1µM concentrations. Rimonabant partially reversed spiking suppression of 5F-PB-22 and, to a lesser extent, of MAM-2201, supporting CB1-mediated involvement, although the inactive WIN 55,212-3 also partially suppressed activity. Taken together, synthetic cannabinoid CB1-mediated suppression of neuronal activity was detected using Ca(2+) spiking and MEAs.

Synthesis and photochemical properties of PEGylated coumarin-caged ceramides for cell studies.

Caged ceramide analogues (C6-, C16-, C18-, C22- and C24-Cer) have been prepared by introducing a hydrophilic coumarin-based cage bearing a short polyethylene glycol (PEG) chain. (6-Bromo-7-mTEGylated-coumarin-4-yl)methyl (Btc) caged ceramide showed efficient photo-uncaging to release the parent ceramide upon direct exposure to 350 nm UV light; in contrast (7-mTEGylated-coumarin-4-yl)methyl (Tc) caged ceramide was photolysed more slowly. In preliminary experiments, Btc-caged ceramides were taken up by cells and their photolysis led to decreases in cell viability, but not to activation of caspase enzymes, suggesting that either reactive oxygen species or an alternate caspase-independent pathway may be responsible for the decreases in cell viability caused by photolysis of caged ceramides.

Cerebral Ischemia Induced Proteomic Alterations: Consequences for the Synapse and Organelles

Willard J. Costain1, Arsalan S. Haqqani2, Ingrid Rasquinha1, Marie-Soleil Giguere2 and Jacqueline Slinn3 1Glycosyltransferases and Neuroglycomics, Institute for Biological Sciences, National Research Council, Ottawa, ON, 2Proteomics, Institute for Biological Sciences, National Research Council, Ottawa, ON, 3Cerebrovascular Research, Institute for Biological Sciences, National Research Council, Ottawa, ON, Canada

Analysis of the pharmacological properties of JWH-122 isomers and THJ-2201, RCS-4 and AB-CHMINACA in HEK293T cells and hippocampal neurons

Abstract Synthetic cannabinoids are marketed as legal alternatives to &Dgr;9‐THC, and are a growing worldwide concern as these drugs are associated with severe adverse effects. Unfortunately, insufficient information regarding the physiological and pharmacological effects of emerging synthetic cannabinoids (ESCs) makes their regulation by government authorities difficult. One strategy used to evade regulation is to distribute isomers of regulated synthetic cannabinoids. This study characterized the pharmacological properties of a panel of ESCs in comparison to &Dgr;9‐THC, as well as six JWH‐122 isomers relative to its parent compound (JWH‐122‐4). Two cell‐based assays were used to determine the potency and efficacy of ESCs and a panel of reference cannabinoids. HEK293T cells were transfected with human cannabinoid receptor 1 (CB1) and pGloSensor‐22F, and the inhibition of forskolin‐stimulated cyclic adenosine monophosphate (cAMP) levels was monitored in live cells. All ESCs examined were classified as agonists, with the following rank order of potency: Win 55,212‐2 > CP 55,940 > JWH‐122‐4 > &Dgr;9‐THC ≈ RCS‐4 ≈ THJ‐2201 > JWH‐122‐5 > JWH‐122‐7 > JWH‐122‐2 ≈ AB‐CHMINACA > JWH‐122‐8 > JWH‐122‐6 > JWH‐122‐3. Evaluation of ESC‐stimulated Ca2+ transients in cultured rat primary hippocampal neurons confirmed the efficacy of four of the most potent ESCs (JWH‐122‐4, JWH‐122‐5, JWH‐122‐7 and AB‐CHMINACA). This work helps regulatory agencies make informed decisions concerning these poorly characterized recreational drugs.