3-Quinuclidinyl benzilate (agent BZ) toxicokinetics in rats.

3-Quinuclidinyl benzilate (BZ) ranks among incapacitating military warfare agents. It acts as a competitive inhibitor on muscarinic receptors leading to non-lethal mental impairment. The present study aimed to investigate toxicokinetics of BZ in rats. Moreover, BZ can be exploited to produce a pharmacological model of Alzheimer's disease; thus, this paper focuses mainly on the BZ distribution to the brain. Wistar rats were administered i.p. with BZ (2 and 10 mg/kg). The BZ concentration was determined using LC-MS/MS in plasma, urine, bile, brain, kidney and liver. The sample preparation was based on a solid phase extraction (liquids) or protein precipitation (organ homogenates). The plasma concentration peaked at 3 min (204.5 ± 55.4 and 2185.5 ± 465.4 ng/ml). The maximal concentration in the brain was reached several minutes later. Plasma elimination half-life was 67.9 ± 3.4 in the 2 mg/kg group and 96.6 ± 27.9 in the 10 mg/kg group. BZ concentrations remained steady in the brain, with slow elimination (t1/2 506.9 ± 359.5 min). Agent BZ is excreted mainly via the urine. Steady BZ concentration in the brain could explain the previously published duration of the significant impairment in passive avoidance tasks in rats after an injection of BZ.

In vitro and in vivo metabolism of 3-quinuclidinyl benzilate by high-resolution mass spectrometry.

3-Quinuclidinyl benzilate (QNB) is an anticholinergic compound that affects the nervous system. Its hallucinogenic action has led to its potential utility as an incapacitating warfare agent, and it is listed in Schedule 2 by the Organization for the Prohibition of Chemical Weapons. Although this compound has been known for a long time, limited information is available regarding its metabolism and mass spectrometric data of the metabolites, the information that could facilitate the identification of QNB in case of suspected intoxication. To the best of our knowledge, the analytical methods previously described in the literature are based on outdated procedures, which may result in a significantly lower number of observable metabolites. The aim of this work was to obtain deeper insight into QNB biotransformation using a combination of in vitro and in vivo approach. The development of a suitable method for the separation and detection of metabolites using mass spectrometry together with the identification of reliable diagnostic fragments for the unambiguous identification of QNB metabolites in the different biological matrices are also presented in this work. A screening of rat plasma, urine and tissue homogenates revealed 26 new metabolites related to the cytochrome P450 biotransformation pathway, which involves N-oxidation and hydroxylation(s) followed by O-methylation and O-glucuronosylation within phase II of the metabolism. A study showed that the brain is not metabolically active in the case of QNB and that the metabolites do not cross the blood-brain barrier; thus, the toxicodynamic effects are due to QNB itself. In addition, in vitro experiments performed using isolated human liver microsomes revealed N-oxidation as the principal metabolic pathway in human tissue. In light of current global events, the abuse of QNB by terrorists or para-military groups is a real possibility, and our findings may improve the detection systems used in laboratories involved in postexposure investigations.

Simple validated method of LC-MS/MS determination of BZ agent in rat plasma samples.

Agent BZ (3-quinuclidinyl benzilate) is a centrally acting synthetic anticholinergic agent, considered as a potential military incapacitating chemical warfare agent. Despite its significance as a model compound in pharmacological research and its potential misuse in chemical attacks, few modern analytical methods for BZ determination in biological samples have been published. The goal of the present work is to develop and validate a sensitive and rapid LC-MS/MS method for the determination of agent BZ in rat plasma. The sample preparation was based on solid-phase extraction on C-18 cartridges. The reversed-phase HPLC coupled with the mass spectrometer with electrospray ionization in the positive ion-selective reaction monitoring mode was employed in the BZ analysis. Atropine was used as an internal standard. The presented method is selective, accurate, precise, and linear (r2 = 0.9947) in a concentration range from 0.5 ng/mL to 1 000 ng/mL and sensitive enough (limit of detection 0.2 ng/mL; limit of quantification 0.5 ng/mL) to determine the BZ plasma levels in rats exposed to 2 mg/kg and 10 mg/kg of BZ. The highest level of BZ in plasma was observed 5 minutes after intramuscular administration (154.6 ± 22.3 ng/mL in rats exposed to 2 mg/kg of BZ and 1024 ± 269 ng/mL in rats exposed to 10 mg/kg). After 48 h, no BZ was observed at detectable levels. This new method allows the detection and quantification of BZ in biological samples after exposure of an observed organism and it will be further optimized for other tissues to observe the distribution of BZ in organs.

A convenient synthesis of the muscarinic cholinergic antagonist (R)-[N-methyl-3 H]quinuclidinyl benzilate methiodide.

A useful synthesis of (R)-[N-methyl-3 H]quinuclidinyl benzilate methiodide is described with the product characterized by thin-layer chromatography (TLC), high-performance liquid chromatography (HPLC), tritium nuclear magnetic resonance (NMR), and mass spectrometry (MS). Several methods are provided to purify the radioligand, and its storage and stability are also discussed.

Unexpected decrease in in vivo binding of [3H]QNB in the mouse cerebral cortex in the developing brain - A comparison with [11C]NMPB.

INTRODUCTION: Significant discrepancies between in vitro and in vivo binding of the muscarinic receptor ligand - 3H-labeled Quinuclidinyl Benzilate (QNB) - have been well documented. Discernable in vivo cerebellar [3H]QNB binding has been observed in mouse brain, despite the maximum number of binding sites (Bmax) being low. In order to understand this unique in vivo binding phenomenon, the binding of two muscarinic receptor ligands - [3H]QNB and N-[11C]methylpiperidyl Benzilate ([11C]NMPB) - were compared in vivo and in vitro in 3- and 8-week-old mice. METHOD: In vitro binding parameters of [3H]QNB were determined using brain homogenates. The time course of radioactivity concentration (TACs) in the cerebral cortex and cerebellum was measured following injection of [3H]QNB and [11C]NMPB with or without 3 mg/kg of carrier QNB in 3- and 8 week old mice using a dual tracer administration technique. A graphical method was employed for the quantitative analysis of in vivo binding of these radioligands. RESULTS: In vitro, the available number of binding sites for cerebral cortical muscarinic receptors increased by 17% during the developmental period studied. Paradoxically, in vivo, we observed a decrease of [3H]QNB binding in the cerebral cortex, while [11C]NMPB binding was markedly increased. In vivo saturation analysis of [3H]QNB in 3-week-old mice revealed an apparent positive cooperativity of binding in the cerebral cortex. CONCLUSIONS: Our results support the hypothesis that microenvironmental factors proximal to muscarinic receptors cause a local decrease in the cortical free-ligand concentration of [3H]QNB and that this 'ligand barrier' is modulated during brain development. ADVANCES IN KNOWLEDGE: The present study demonstrates that the combined use of radiolabeled QNB and NMPB has the potential to reveal the important effects of receptor microenvironmental factors on receptor function in the living brain.

Spinalization and locomotor training differentially affect muscarinic acetylcholine receptor type 2 abutting on α-motoneurons innervating the ankle extensor and flexor muscles.

Complete thoracic spinal cord transection (SCT) impairs excitatory cholinergic inputs to ankle extensor (soleus; Sol) but not to flexor (tibialis anterior; TA) α-motoneurons (MNs) modifiable by locomotor training applied post-transection. The purpose of this study was to investigate whether Sol and TA MNs adapt to changes in cholinergic environment by differential regulation of their muscarinic receptors M2 (M2R). We examined Chrm2 (M2R gene) transcript level, high-affinity 3-quinuclidinyl benzilate-3 H ([3 H]QNB) ligand binding, distribution and density of M2R immunolabeling in lumbar (L) segments in intact and SCT rats, with or without inclusion of 5-week treadmill locomotor training. We show that at the second week after SCT the levels of Chrm2 transcript are reduced in the L3-6 segments, with [3 H]QNB binding decreased selectively in the L5-6 segments, where ankle extensor MNs are predominantly located. At 5 weeks after SCT, [3 H]QNB binding differences between the L3-4 and L5-6 segments are maintained, accompanied by higher density of M2R immunolabeling in the plasma membrane and cytoplasm of TA than Sol MNs and by enriched synaptic versus extrasynaptic M2R pools (52% TA vs. 25% Sol MNs). Training normalized M2R in TA MNs, improved locomotion, and reduced frequency of clonic episodes. Our findings indicate higher sensitivity of TA than Sol MNs to cholinergic signaling after SCT, which might shorten flexor twitches duration and contribute to generation of clonic movements. Synaptic enrichment in M2R density may reflect a compensatory mechanism activated in TA and Sol MNs to different extent in response to reduced strength of cholinergic signaling to each MN pool. Open Practices Open Science: This manuscript was awarded with the Open Materials Badge. For more information see: https://cos.io/our-services/open-science-badges/.

Novel Stability-Indicating Chemometric-Assisted Spectrophotometric Methods for the Determination of Chlordiazepoxide and Clidinium Bromide in the Presence of Clidinium Bromide's Alkali-Induced Degradation Product.

Two simple and accurate chemometric-assisted spectrophotometric models were developed and validated for the simultaneous determination of chlordiazepoxide (CDZ) and clidinium bromide (CDB) in the presence of an alkali-induced degradation product of CDB in their pure and pharmaceutical formulation. Resolution was accomplished by using two multivariate calibration models, including principal component regression (PCR) and partial least-squares (PLS), applied to the UV spectra of the mixtures. Great improvement in the predictive abilities of these multivariate calibrations was observed. A calibration set was constructed and the best model used to predict the concentrations of the studied drugs. CDZ and CDB were analyzed with mean accuracies of 99.84 ± 1.41 and 99.81 ± 0.89% for CDZ and 99.56 ± 1.43 and 99.44 ± 1.41% for CDB using PLS and PCR models, respectively. The proposed models were validated and applied for the analysis of a commercial formulation and laboratory-prepared mixtures. The developed models were statistically compared with those of the official and reported methods with no significant differences observed. The models can be used for the routine analysis of both drugs in QC laboratories.

An improved, high-efficiency assay for assessing serum anticholinergic activity using cultured cells stably expressing M1 receptors.

Assessments of total anticholinergic activity (SAA) in serum are of considerable interest for its potential involvement in cognitive impairment associated with polydrug states in the elderly and other populations. Such estimations have been based on the displacement of radioligand binding in rat brain tissues. The validity of such measurements has been questioned, as a potentially distorting effect of large serum proteins was identified. We sought to develop a modified assay that would be more efficient and free of this potential confound. Cultured CHO cells stably expressing M1 receptors M1WT3 were used. Binding of 3H-radioligands was conducted in 96-well plates and tested in serum containing known amounts of anticholinergic medications. Effects of endogenous serum proteins were assessed by pre-assay filtration and also by deproteinization with perchloric acid (PCA). Binding of [3H]quinuclidinyl benzilate ([3H]QNB) or [3H]N-methyl-scopolamine ([3H]NMS) to M1WT3 cells proved reliable and equally sensitive to varying concentrations of anticholinergic agents. In agreement with previous findings (Cox, Kwatra, Shetty, & Kwatra, 2009), filtration of proteins heavier than 50kDa essentially reduced SAA values to zero. In contrast, PCA preserved more than 70% of the binding seen untreated cell membranes. Cell-based assays also showed significant signal increases compared to the conventional rat brain-based protocol. Further advantages of the cell-based protocol described here include increased sensitivity and reliability, smaller amounts of radioligand needed, and higher throughput. PCA pretreatment eliminates potential artifacts attributable to serum proteins. This step, together with improvements in efficiency, should contribute significantly to the usefulness of the assay.

Graded activation and free energy landscapes of a muscarinic G-protein-coupled receptor.

G-protein-coupled receptors (GPCRs) recognize ligands of widely different efficacies, from inverse to partial and full agonists, which transduce cellular signals at differentiated levels. However, the mechanism of such graded activation remains unclear. Using the Gaussian accelerated molecular dynamics (GaMD) method that enables both unconstrained enhanced sampling and free energy calculation, we have performed extensive GaMD simulations (∼19 µs in total) to investigate structural dynamics of the M2 muscarinic GPCR that is bound by the full agonist iperoxo (IXO), the partial agonist arecoline (ARC), and the inverse agonist 3-quinuclidinyl-benzilate (QNB), in the presence or absence of the G-protein mimetic nanobody. In the receptor-nanobody complex, IXO binding leads to higher fluctuations in the protein-coupling interface than ARC, especially in the receptor transmembrane helix 5 (TM5), TM6, and TM7 intracellular domains that are essential elements for GPCR activation, but less flexibility in the receptor extracellular region due to stronger binding compared with ARC. Two different binding poses are revealed for ARC in the orthosteric pocket. Removal of the nanobody leads to GPCR deactivation that is characterized by inward movement of the TM6 intracellular end. Distinct low-energy intermediate conformational states are identified for the IXO- and ARC-bound M2 receptor. Both dissociation and binding of an orthosteric ligand are observed in a single all-atom GPCR simulation in the case of partial agonist ARC binding to the M2 receptor. This study demonstrates the applicability of GaMD for exploring free energy landscapes of large biomolecules and the simulations provide important insights into the GPCR functional mechanism.

Effects of novel tacrine-related cholinesterase inhibitors in the reversal of 3-quinuclidinyl benzilate-induced cognitive deficit in rats--Is there a potential for Alzheimer's disease treatment?

Inhibitors of cholinesterase are important drugs for therapy of Alzheimer's disease and the search for new modifications is extensive, including dual inhibitors or multi-target hybrid compounds. The aim of the present study was a preliminary evaluation of pro-cognitive effects of newly-developed 7-MEOTA-donepezil like hybrids (compounds no. 1 and 2) and N-alkylated tacrine derivatives (compounds no. 3 and 4) using an animal model of pharmacologically-induced cognitive deficit. Male Wistar rats were subjected to tests of learning and memory in a water maze and step-through passive avoidance task. Cognitive impairment was induced by 3-quinuclidinyl benzilate (QNB, 2mgkg(-1)), administered intraperitoneally 1h before training sessions. Cholinesterase inhibitors were administered as a single therapeutic dose following the QNB at 30min at the following dose rates; 1 (25.6mgkg(-1)), 2 (12.3mgkg(-1)), 3 (5.7mgkg(-1)), 4 (5.2mgkg(-1)). The decrease in total path within the 10-swim session (water maze), the preference for target quadrant (water maze) and the entrance latency (passive avoidance) were taken as indicators of learning ability in rats. The effects of novel compounds were compared to that of standards tacrine (5.2mgkg(-1)) and donepezil (2.65mgkg(-1)). QNB significantly impaired spatial navigation as well as fear learning. Generally, the performance of rats was improved when treated with novel inhibitors and this effect reached efficiency of standard donepezil at selected doses. There was a significant improvement in the groups treated with compounds 2 and 3 in all behavioral tasks. The rest of the novel compounds succeed in the passive avoidance test. In summary, the potential of novel inhibitors (especially compounds 2 and 3) was proved and further detailed evaluation of these compounds as potential drugs for Alzheimer's disease treatment is proposed.

Memetic algorithms for ligand expulsion from protein cavities.

Ligand diffusion through a protein interior is a fundamental process governing biological signaling and enzymatic catalysis. A complex topology of channels in proteins leads often to difficulties in modeling ligand escape pathways by classical molecular dynamics simulations. In this paper, two novel memetic methods for searching the exit paths and cavity space exploration are proposed: Memory Enhanced Random Acceleration (MERA) Molecular Dynamics (MD) and Immune Algorithm (IA). In MERA, a pheromone concept is introduced to optimize an expulsion force. In IA, hybrid learning protocols are exploited to predict ligand exit paths. They are tested on three protein channels with increasing complexity: M2 muscarinic G-protein-coupled receptor, enzyme nitrile hydratase, and heme-protein cytochrome P450cam. In these cases, the memetic methods outperform simulated annealing and random acceleration molecular dynamics. The proposed algorithms are general and appropriate in all problems where an accelerated transport of an object through a network of channels is studied.

Muscarinic drugs regulate the PKG-II-dependent phosphorylation of M3 muscarinic acetylcholine receptors at plasma membranes from airway smooth muscle.

Muscarinic agonists induce the activation of the airway smooth muscle (ASM) leading to smooth muscle contraction, important in asthma. This activation is mediated through M2/M3 muscarinic acetylcholine receptors (mAChRs). Muscarinic receptor activity, expressed as [(3)H]QNB binding at plasma membranes from bovine tracheal smooth muscle (BTSM), increased with cGMP and was augmented significantly cGMP plus ATP but diminished with the PKG-II inhibitor, Sp-8-pCPT-cGMPS. The [(3)H]-QNB binding was accelerated by okadaic acid, (OKA), a protein phosphatase (PPase) inhibitor. These two results indicated the involvement of a membrane-bound PPase. Moreover, a cGMP-dependent-[(32)P]γATP phosphorylation of plasma membranes from BTSM was stimulated at low concentrations of muscarinic agonist carbamylcholine (CC). However, higher amounts of CC produced a significant decrement of [(32)P]-labeling. A selective M3mAChR antagonist, 4-DAMP produced a dramatic inhibition of the basal and CC-dependent [(32)P]-labeling. The [(32)P] labeled membrane sediments were detergent solubilized and immunoprecipitated with specific M2/M3mAChR antibodies. The M3mAChR immuno-precipitates exhibited the highest cGMP-dependent [(32)P]-labeling, indicating it is a PKG-II substrate. Experiments using synthetic peptides from the C-terminal of the third intracellular loop (i3) of both M2mAChR (356-369) and M3mAChR (480-493) as external PKG-II substrates resulted in the i3M3-peptide being heavily phosphorylated. These results indicated that PKG-II phosphorylated the M3mAChR at the i3M3 domain ((480)MSLIKEKK(485)), suggesting that Ser(481) may be the target. Finally, this phosphorylation site seems to be regulated by a membrane-bound PPase linked to muscarinic receptor. These findings are important to understand the role of M3mAChR in the patho-physiology of ASM involved in asthma and COPD.

Constipation enhances the propensity to seizure in pentylenetetrazole-induced seizure models of mice.

Epilepsy is characterized by spontaneous recurrent seizures and represents one of the most frequent neurological diseases, affecting about 60 million people worldwide. The cellular and neurocircuit bases of epilepsy are poorly understood. Constipation is a common gastrointestinal disorder characterized by symptoms such as straining, hard stool, and infrequent defecation. Population-based studies have shown that the prevalence of constipation is up to 30% of the population in developed countries. The causal link between seizure and constipation is a common belief among patients and physicians, but there are no scientific data to support this association. The current investigation evaluated the effects of constipation induced by loperamide (a peripheral µ-opioid receptor agonist without effect on central nervous system receptors) and clidinium (a quaternary amine antimuscarinic agent with reduced central nervous system effects) on two different seizure models of mice: (1) myoclonic, clonic, and generalized tonic seizures and death induced by intraperitoneal administration of pentylenetetrazole and (2) clonic seizure threshold induced by intravenous infusion of pentylenetetrazole. We demonstrated that the measured intestinal transit (%intestinal transit) decreased after loperamide or clidinium treatment for 3days. Constipation in mice which was induced by loperamide or clonidine caused a decrease in threshold to clonic seizure in the intravenous pentylenetetrazole seizure model. Moreover loperamide- or clidinium-induced constipation decreased latencies to, clonic, and tonic seizures and death in the intraperitoneal pentylenetetrazole model of mice. Serum ammonia levels were slightly elevated in both loperamide- and clidinium-treated mice. In conclusion, loperamide- or clidinium-induced constipated mice are more prone to seizure which might confirm the belief of patients and physicians about constipation as a trigger of seizure.

The effects of novel 7-MEOTA-donepezil like hybrids and N-alkylated tacrine analogues in the treatment of quinuclidinyl benzilate-induced behavioural deficits in rats performing the multiple T-maze test.

AIMS: The number of approved drugs for the clinical treatment of Alzheimer disease remains limited. For this reason, there is extensive search for novel therapies. Of these, cholinesterase inhibitors have some proven benefit in slowing the disease progression and still remain the first-line therapeutic approach. In this study, the pro-cognitive effect of four novel tacrine-related inhibitors was evaluated and compared with the standards, tacrine and donepezil. METHODS: Wistar rats trained to perform the multiple T-maze were treated intra-peritoneally with the anticholinergic agent 3-quinuclidinyl benzilate (QNB, 2.0 mg/kg), followed 30 min later by another injection containing a therapeutic dose of standard or novel cholinesterase inhibitor. The rats were repeatedly subjected to the multiple T-maze task at several time points following QNB administration (1, 24, 48 and 72 h). The passage time and number of errors were recorded. The inhibitory potential of selected therapeutic doses was assessed in a separate in vivo experiment using a spectrophotometric method. RESULTS: QNB significantly impaired the performance of the rats within 48 h. The four novel cholinesterase inhibitors attenuated the effect of QNB at 1 h, 24 h and 48 h test intervals. The novel compounds resulted in brain cholinesterase inhibition ranging from 5.4 to 11.3 %, and their effect on the QNB-induced deficit recorded in the T-maze performance was comparable to that of the standards or higher at some time points. CONCLUSION: The best result was achieved with derivative 4, followed by derivatives 2 and 3, suggesting that these compounds could be candidates for the treatment of Alzheimer disease.

Small longitudinal study of serum anticholinergic activity and cognitive change in community-dwelling older adults.

OBJECTIVE: The discriminative ability of serum anticholinergic activity (SAA) to differentiate between older individuals with stable versus deteriorating cognition remains undetermined. We examined the relationship between SAA changes, the presence or absence of a mild neurocognitive disorder, age and anticholinergic medication over a one-year time period. METHODS: SAA at baseline and one-year follow-up was measured for 121 older adults without dementia. Participants were classified at both timepoints as being cognitively intact or meeting the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition (DSM-5) criteria for a mild neurocognitive disorder. Medications were assessed according to the Anticholinergic Cognitive Burden (ACB) scale. RESULTS: SAA changes did not discriminate between individuals whose cognition remained stable versus those with improvement or decline (H[3]=0.725, p=0.867). SAA change did not vary between age groups, and could not reliably differentiate between individuals on ACB medication or not. CONCLUSION: While SAA does not appear to be a valid biomarker for cognitive decline, longitudinal studies with a larger sample size and longer duration are required to confirm this finding.

Cholinergic antagonist 3-quinuclidinyl benzilate - Impact on learning and memory in Wistar rats.

3-Quinuclidinyl benzilate (QNB) represents a non-selective, competitive antagonist of cholinergic receptors, which has been previously used to generate cognitive deficits in animal models of neurodegenerative disorders. The aim of this study was evaluation of QNB potency for creation of cognitive impairment during the acquisition, consolidation and retrieval stages of learning and memory in rats. Male Wistar rats were subjected to a water maze task with hidden platform and a step-through passive avoidance task. The water maze test was carried out in two separate experiments focused on spatial learning (acquisition test) and long-term spatial memory (retrieval test). QNB doses (0.5, 1.0, 2.0 and 5.0 mg kg(-1)) were administered to rats intraperitoneally before training sessions (acquisition test) or before probe trial (retrieval test). A QNB dose of 2.0 mg kg(-1) was administered to rats in the passive avoidance task before training (acquisition test), immediately post-training (consolidation test) or 24h pre-retention (retrieval test). QNB significantly impaired the acquisition in the water maze at doses 0.5-5.0 mg kg(-1) as well as the acquisition of passive avoidance task. In contrast, consolidation and retrieval were not affected by QNB, indicating that QNB specifically affects the stage of acquisition.

Cyclic GMP regulates M3AChR activity at plasma membranes from airway smooth muscle.

Muscarinic acetylcholine receptors MAChRs from Bovine Tracheal Smooth Muscle (BTSM) plasma membranes are responsible for the cGMP rise and signal-amplitude peaks associated with smooth muscle contraction present in bronchial asthma. These MAChRs bind [(3)H]QNB and exhibit the classic G Protein Coupled-Receptor (GPCR) behavior towards muscarinic agonist and antagonists that is sensitive to sensitive to GTP analogs. Interestingly, the [(3)H]QNB binding activity was stimulated by cGMP and ATP, and was enhanced by IBMX and Zaprinast, inhibitors of cGMP-PDE. Cyclic GMP plus ATP affected the agonist-antagonist muscarinic binding activities. Thus, the high affinity agonist (Carbamylcholine) binding sites disappeared, whereas, 4-DAMP, a M3 selective antagonist displayed an additional high affinity-binding site. In contrast, non-selective (atropine) and M2-selective (methoctramine and gallamine) antagonists revealed one low binding site. Moreover, the 4-DAMP-mustard alkylation of the MAChRs blocked the cGMP effect indicating that the M3AChR is the main receptor target of cGMP. Interestingly, these cGMP effects were potentiated by an activator (Sp-8-pCPT-cGMPS), and diminished by an inhibitor (Rp-8-pCPT-CGMPS), of cGMP-dependent protein kinase (PKG-II), which was detected by Western blotting using specific PKG II antibodies. Finally, plasma membrane M3AChRs were phosphorylated in a cGMP-dependent manner and this novel post-translational reversible modification at M3AChRs may act as a feedback mechanism to terminate the cGMP dependent muscarinic signal transduction cascades at the sarcolema of BTSM.

Comparison of subcellular distribution and functions between exogenous and endogenous M1 muscarinic acetylcholine receptors.

AIMS: Recombinant systems have been used for evaluating the properties of G-protein-coupled receptors (GPCRs) on the assumption of cell surface expression. However, many GPCRs, including muscarinic acetylcholine receptors (mAChRs), have also been reported to be distributed in intracellular organelles in native tissues and cell lines. In this study, we compared the pharmacological profiles of exogenously and endogenously expressed M1-mAChRs, and evaluated the functional properties of these receptors. MAIN METHODS: Recombinant M1-mAChRs were expressed exogenously in Chinese hamster ovary cells (CHO-M1 cells) and compared with endogenously expressed M1-mAChRs in N1E-115 neuroblastoma cells. The pharmacological and functional profiles were evaluated using cell-permeable antagonists (1-quinuclidinyl-benzilate (QNB), pirenzepine and atropine) and cell-impermeable antagonists (N-methylscopolamine (NMS) or MT-7). KEY FINDINGS: M1-mAChRs were seen at the cell surface and intracellular sites in both cell lines. Under whole cell conditions, intracellular M1-mAChRs were mainly recognized by cell-permeable ligands, but scarcely by cell-impermeable ligands (at less than 100nM). In CHO-M1 cells, M1-mAChR activation by carbachol resulted in Ca(2+) mobilization, ERK1/2 phosphorylation and a reduction in thymidine incorporation, all of which were completely inhibited by MT-7, indicating the involvement of surface M1-mAChRs. In N1E-115 cells, Ca(2+) mobilization occurred through surface M1-mAChRs, whereas ERK1/2 phosphorylation and acceleration of thymidine incorporation were mediated through intracellular M1-mAChRs. SIGNIFICANCE: Exogenous and endogenous M1-mAChRs are present at both the cell surface and the intracellular organelles, and the pharmacological properties of geographically distinct M1-mAChRs are different, and may depend on cell background and/or exogenous or endogenous origin.

Decreased binding capacity (Bmax) of muscarinic acetylcholine receptors in fibroblasts from boys with attention-deficit/hyperactivity disorder (ADHD).

Monoaminergic dysregulation is implicated in attention-deficit/hyperactivity disorder (ADHD), and methylphenidate and amphetamines are the most frequently prescribed pharmacological agents for treating ADHD. However, it has recently been proposed that the core symptoms of the disorder might be due to an imbalance between monoaminergic and cholinergic systems. In this study, we used fibroblast cell homogenates from boys with and without ADHD as an extraneural cell model to examine the cholinergic receptor density, that is, muscarinic acetylcholine receptors (mAChRs). We found that the binding capacity (Bmax) of [³H] Quinuclidinyl benzilate (³H-QNB) to mAChRs was decreased by almost 50 % in the children with ADHD (mean = 30.6 fmol/mg protein, SD = 25.6) in comparison with controls [mean = 63.1 fmol/mg protein, SD = 20.5, p ≤ 0.01 (Student's unpaired t test)]. The decreased Bmax indicates a reduced cholinergic receptor density, which might constitute a biomarker for ADHD. However, these preliminary findings need to be replicated in larger ADHD and comparison cohorts.

Biological sex influences learning strategy preference and muscarinic receptor binding in specific brain regions of prepubertal rats.

According to the theory of multiple memory systems, specific brain regions interact to determine how the locations of goals are learned when rodents navigate a spatial environment. A number of factors influence the type of strategy used by rodents to remember the location of a given goal in space, including the biological sex of the learner. We recently found that prior to puberty male rats preferred a striatum-dependent stimulus-response strategy over a hippocampus-dependent place strategy when solving a dual-solution task, while age-matched females showed no strategy preference. Because the cholinergic system has been implicated in learning strategy and is known to be sexually dimorphic prior to puberty, we explored the relationship between learning strategy and muscarinic receptor binding in specific brain regions of prepubertal males and female rats. We confirmed our previous finding that at 28 days of age a significantly higher proportion of prepubertal males preferred a stimulus-response learning strategy than a place strategy to solve a dual-solution visible platform water maze task. Equal proportions of prepubertal females preferred stimulus-response or place strategies. Profiles of muscarinic receptor binding as assessed by autoradiography varied according to strategy preference. Regardless of biological sex, prepubertal rats that preferred stimulus-response strategy exhibited lower ratios of muscarinic receptor binding in the hippocampus relative to the dorsolateral striatum compared to rats that preferred place strategy. Importantly, much of the variance in this ratio was related to differences in the ventral hippocampus to a greater extent than the dorsal hippocampus. The ratios of muscarinic receptors in the hippocampus relative to the basolateral amygdala also were lower in rats that preferred stimulus-response strategy over place strategy. Results confirm that learning strategy preference varies with biological sex in prepubertal rats with males biased toward a stimulus-response strategy, and that stimulus-response strategy is associated with lower ratios of muscarinic binding in the hippocampus relative to either the striatum or amygdala.