In vitro binding of a radio-labeled positive allosteric modulator for metabotropic glutamate receptor subtype 5.

The positive allosteric modulator (PAM) binding site for metabotropic glutamate receptor subtype 5 (mGlu(5)) lacks a readily available radio-labeled tracer fordetailed structure-activity studies. This communication describes a selective mGlu(5) compound, 7-methyl-2-(4-(pyridin-2-yloxy)benzyl)-5-(pyridin-3-yl)isoindolin-1-one (PBPyl) that binds with high affinity to human mGlu(5) and exhibits functional PAM activity. Analysis of PBPyl by FLIPR revealed an EC(50) of 87 nM with an 89% effect in transfected HEK293 cells and an EC(50) of 81 nM with a 42% effect in rat primary neurons. PBPyl exhibited 5-fold higher functional selectivity for mGlu(5) in a full mGlu receptor panel. Unlabeled PBPyl was tested for specific binding using a liquid chromatography mass spectrometry (LC/MS/MS)-based filtration binding assay and exhibited 40% specific binding in recombinant membranes, a value higher than any candidate compound tested. In competition binding studies with [(3)H]MPEP, the mGlu(5) receptor negative allosteric modulator (NAM), PBPyl exhibited a k(i) value of 34 nM. PBPyl also displaced [(3)H]ABP688, a mGluR(5) receptor NAM, in tissue sections from mouse and rat brain using autoradiography. Areas of specific binding included the frontal cortex, striatum and nucleus accumbens. PBPyl was radiolabeled to a specific activity of 15 Ci/mmol and tested for specific binding in a filter plate format. In recombinant mGlu(5b) membranes, [(3)H] PBPyl exhibited saturable binding with a K(d) value of 18.6 nM. In competition binding experiments, [(3)H] PBPyl was displaced by high affinity mGlu(5) positive and negative modulators. Further tests showed that PBPyl displays less than optimal characteristics as an in vivo tool, including a high volume of distribution and ClogP, making it more suitable as an in vitro compound. However, as a first report of direct binding of an mGlu(5) receptor PAM, this study offers value toward the development of novel PET imaging agents for this important therapeutic target.

[³H]Chiba-1001(methyl-SSR180711) has low in vitro binding affinity and poor in vivo selectivity to nicotinic alpha-7 receptor in rodent brain.

Neuronal nicotinic acetylcholine receptor (nAChR) agonists active at the alpha-7 (α-7) receptor subtype are potential therapeutics for cognitive deficits in schizophrenia, Alzheimer's disease, and other mental disorders. SSR180711, an α-7 selective partial agonist, has been shown to improve preclinical cognition. A novel positron emission tomography (PET) radioligand, ¹¹C-Chiba1001, is a close analog of SSR180711. We labeled Chiba-1001 with tritium in order to evaluate its utility as a preclinical radioligand tool. In vitro, the binding affinity of [³H]Chiba-1001 at the α-7 receptor was low (K(d) = 120-180 nM) in both HEK239 cell membranes expressing human α-7 receptor and in native rat hippocampus membranes. The α-7 selective ligands AZD0328, ARR17779, and MLA did not inhibit [³H]Chiba-1001 binding (K(i) > 10,000 nM). In rat hippocampal membranes, Chiba-1001 and SSR180711 inhibited [³H]Chiba-1001 binding (K(i) = 220 and 230 nM, respectively), consistent with the literature reports. The in vivo binding profile of the radioligand was examined in normal rat, wild type mouse, and α-7 knockout mouse brain. We found that [³H]Chiba-1001 lacks adequate and specific brain regional uptake in rat and mouse brain. No significant inhibition of the radioligand binding was obtained following pretreatment of the animal with AZ11637326, AZD0328, or MLA. Our results indicate that [³H]Chiba-1001 has low affinity for α-7 nAChRs in vitro and poor α-7 regional and pharmacological selectivity in the rodent brain.

Absence of direct effects on the dopamine D2 receptor by mGluR2/3-selective receptor agonists LY 354,740 and LY 379,268.

We previously reported the absence of high-affinity binding of the group II metabotropic glutamate receptor agonists LY 354,740 and LY 379,268 to the D2L dopamine receptor. A rebuttal to our findings has since been reported (see Introduction section); this study represents our response. Analysis by LCMS of LY 354,740 and LY 379,268 used in this study revealed the correct molecular mass for these compounds. Both LY 354,740 and LY 379,268 exhibited potent agonist activity for mGluR2 in the ³5S-GTPγS assay. Functionally, neither compound displayed antagonist activity in the GTPγS assay with recombinant D2. At concentrations up to 10 µM, both compounds failed to displace [³H]-raclopride, [³H]-PHNO, or [³H]-domperidone in filter-binding assays under isotonic (120 mM NaCl or N-methyl glucamine) or low-ionic strength (no NaCl or N-methyl glucamine) conditions. Some displacement of [³H]-domperidone (20-40%) was observed at 30 µM of LY 354,740 under low-ionic strength and under isotonic conditions in the absence of NaCl. No displacement of [³H]-domperidone was detected in a two site model at lower (<100 nM) concentrations of either compound. Moreover, no D2 activity was observed for LY 354,740 or LY 379,268 in the CellKey™ (cellular dielectric spectroscopy) assay. In this communication, we discuss the possible reasons for differences in our study and the previously published work and implications of these studies for mechanisms of antipsychotic action.

D2 receptor occupancy in conscious rat brain is not significantly distinguished with [3H]-MNPA, [3H]-(+)-PHNO, and [3H]-raclopride.

Positron emission tomography (PET) antagonist ligands such as [(11)C]-raclopride are commonly used to study dopamine D2 receptor (D2) binding of antipsychotics. It has been suggested that agonist radioligands bind preferentially to the high-affinity state of D2 receptor and may provide a more relevant means of assessing D2 occupancy. The main objective of this study was to determine if D2 receptor occupancy (RO) could be differentiated with agonist and antagonist radioligands in vivo. Agonist radioligands [(3)H]-MNPA and [(3)H]-(+)-PHNO were synthesized and compared to antagonist [(3)H]-raclopride in the in vitro binding and in vivo occupancy studies. In vivo, unanesthetized rats were pretreated with quinpirole (full agonist), aripiprazole (partial agonist), or haloperidol (antagonist) prior to administration of the agonist or antagonist radioligand. All three pretreatment compounds showed equivalent dose-dependent D2 receptor occupancy in the rat striatum with each radioligand. The in vivo receptor occupancy results suggested that the binding of quinpirole, aripiprazole, and haloperidol to the high or low affinity state of the D2 receptor could not be differentiated using radiolabeled agonists or antagonists, presumably due to a predominance of high affinity states of the D2 receptor in vivo. This hypothesis was supported in part by the in vitro binding results. Our in vitro results show that [(3)H]-MNPA binds to D2S transfected CHO cell membranes at a single high affinity site. Displacement of [(3)H]-(+)-PHNO binding by quinpirole and elimination of most [(3)H]-(+)-PHNO binding by the guanine nucleotide GppNHp in striatal membranes suggest that the majority of D2 in striatal tissue is G-protein coupled. Together, these findings suggest that D2 agonist radioligands produce in vivo receptor occupancy comparable to [(3)H]-raclopride.

Whole-mount analysis reveals normal numbers of dopaminergic neurons following misexpression of alpha-Synuclein in Drosophila.

Previously published reports have suggested that misexpression of alpha-Synuclein in the Drosophila central nervous system causes neurodegeneration and progressive age-dependent locomotor dysfunction similar to pathologic and clinical manifestations of Parkinson's disease. The number of dopaminergic (DA) neurons in these studies was assessed using immunohistochemistry with an anti-tyrosine hydroxylase antibody on sequential paraffin sections of fly brains. In contrast, we do not observe any DA cell loss in alpha-Synuclein expressing fly brains when using whole-mount immunohistochemistry as an assay. Our results suggest that the DA cell loss observed with misexpression of alpha-Synuclein is not fully penetrant under a variety of experimental conditions and that this may complicate interpretation of such experiments.

Parkin suppresses wild-type alpha-synuclein-induced toxicity in SHSY-5Y cells.

Current hypotheses concerning the mechanism of neuronal cell death in Parkinson's disease (PD) and related synucleopathies propose a functional interaction between parkin and alpha-synuclein (alphaS). Recently parkin was shown to suppress mutant alphaS-induced toxicity in primary neurons, providing a basis for an association between these proteins and neuronal loss [Neuron 36 (2000) 1007-1019]. We have asked if a similar association could be made between wild-type (wt) alphaS and parkin. We examined inducible over-expression of alphaS in SHSY-5Y cells through adenoviral infection under conditions which produce cellular toxicity through a reduction in ATP levels. We demonstrate that parkin suppresses toxicity induced by mutant (A53T) and wt alphaS. Parkin over-expression was also associated with the appearance of higher molecular weight alphaS-immunoreactive bands by Western blot analysis. These data, consistent with a protective role for parkin, extend previous findings to include a functional association between parkin and the wt form of alphaS.

Linear non-competitive inhibition of solubilized human gamma-secretase by pepstatin A methylester, L685458, sulfonamides, and benzodiazepines.

Cerebral deposition of amyloid beta-protein (A beta) is believed to play a key role in the pathogenesis of Alzheimer's disease. Because A beta is produced from the processing of amyloid beta-protein precursor (APP) by beta- and gamma-secretases, these enzymes are considered important therapeutic targets for identification of drugs to treat Alzheimer's disease. Unlike beta-secretase, which is a monomeric aspartyl protease, gamma-secretase activity resides as part of a membrane-bound, high molecular weight, macromolecular complex. Pepstatin and L685458 are among several structural classes of gamma-secretase inhibitors identified so far. These compounds possess a hydroxyethylene dipeptide isostere of aspartyl protease transition state analogs, suggesting gamma-secretase may be an aspartyl protease. However, the mechanism of inhibition of gamma-secretase by pepstatin and L685458 has not been elucidated. In this study, we report that pepstatin A methylester and L685458 unexpectedly displayed linear non-competitive inhibition of gamma-secretase. Sulfonamides and benzodiazepines, which do not resemble transition state analogs of aspartyl proteases, also displayed potent, non-competitive inhibition of gamma-secretase. Models to rationalize how transition state analogs inhibit their targets by non-competitive inhibition are discussed.