The M1 receptor is required for muscarinic activation of mitogen-activated protein (MAP) kinase in murine cerebral cortical neurons

Muscarinic acetylcholine receptors (mAChR) in the central nervous system are involved in learning and memory, epileptic seizures, and processing the amyloid precursor protein. The M(1) receptor is the predominant mAChR subtype in the cortex and hippocampus. Although the five mAChR fall into two broad functional groups, all five subtypes, when expressed in recombinant systems, can activate the mitogen-activated protein kinase (MAPK) pathway. The MAPK pathway has been implicated in learning and memory, amyloid protein processing, and neuronal plasticity. We used M(1) knock-out mice to determine the role of this receptor subtype in signal transduction in the mouse forebrain. In primary cortical cultures from mice lacking the M(1) mAChR, agonist-stimulated phosphoinositide hydrolysis was reduced by more than 60% compared with cultures from wild type mice. Although muscarinic agonists induced robust activation of MAPK in cortical cultures from wild type mice, mAChR-mediated activation of MAPK was virtually absent in cultures from M(1)-deficient mice. These results indicate that the M(1) mAChR is the major subtype that mediates activation of phospholipase C and MAPK in mouse forebrain.     

Distinct primary structures, ligand-binding properties and tissue-specific expression of four human muscarinic acetylcholine receptors.

To investigate the molecular basis for the diversity in muscarinic cholinergic function, we have isolated the genes encoding the human M1 and M2 muscarinic receptors (mAChR) as well as two previously undiscovered mAChR subtypes, designated HM3 and HM4. The amino acid sequence of each subtype reflects a structure consisting of seven, highly conserved transmembrane segments and a large intracellular region unique to each subtype, which may constitute the ligand-binding and effector-coupling domains respectively. Significant differences in affinity for muscarinic ligands were detected in individual mAChR subtypes produced by transfection of mammalian cells. Each subtype exhibited multiple affinity states for agonists; differences among subtypes in the affinities and proportions of such sites suggest the capacity of mAChR subtypes to interact differentially with the cellular effector-coupling apparatus. Subtype-specific mRNA expression was observed in the heart, pancreas and a neuronal cell line, indicating that the regulation of mAChR gene expression contributes to the differentiation of cholinergic activity.     

The M4 muscarinic receptor-selective effects on keratinocyte crawling locomotion

We have investigated how the cholinergic system of epidermal keratinocytes (KC) controls migratory function of these cells. Several molecular subtypes of muscarinic acetylcholine receptors (mAChRs) have been detected in KC. Early results suggested that M(4) is the predominant mAChR regulating cell motility. To determine muscarinic effects on lateral migration of KC, we used an agarose gel keratinocyte outgrowth system (AGKOS) which provides for measurements of the response of large cell populations (> 10(4) cells). Muscarine produced a dose-dependent stimulatory effect on cell migration (p < 0.05). This activity was abolished by atropine, which decreased migration distance when given alone. To identify the mAChR subtype(s) mediating these muscarinic effects, we substituted atropine with subtype-selective antagonists. Tropicamide (M(4)-selective) was more effective at decreasing the migration distance than pirenzepine and 4-DAMP at nanomolar concentrations. We then compared lateral migration of KC obtained from M(4) mAChR knockout mice with that of wild-type murine KC, using AGKOS. In the absence of M(4) mAChR, the migration distance of KC was significantly (p < 0.05) decreased. These results indicate that the M(4) mAChR plays a central role in mediating cholinergic control of keratinocyte migration by endogenous acetylcholine produced by these cells.     

Muscarinic receptor subtypes involved in hippocampal circuits

Muscarinic receptors modulate hippocampal activity in two main ways: inhibition of synaptic activity and enhancement of excitability of hippocampal cells. Due to the lack of pharmacological tools, it has not been possible to identify the individual receptor subtypes that mediate the specific physiological actions that underlie these forms of modulation. Light and electron microscopic immunocytochemistry using subtype-specific antibodies was combined with lesioning techniques to examine the pre- and postsynaptic location of m1-m4 mAChR at identified hippocampus synapses. The results revealed striking differences among the subtypes, and suggested different ways that the receptors modulate excitatory and inhibitory transmission in distinct circuits. Complementary physiological studies using m1-toxin investigated the modulatory effects of this subtype on excitatory transmission in more detail. The implications of these data for understanding the functional roles of these subtypes are discussed.     

Distinct sequence elements control the specificity of G protein activation by muscarinic acetylcholine receptor subtypes.

Relatively little is understood concerning the mechanisms by which subtypes of receptors, G proteins and effector enzymes interact to transduce specific signals. Through expression of normal, hybrid and deletion mutant receptors in Xenopus oocytes, we determined the G protein coupling characteristics of the functionally distinct m2 and m3 muscarinic acetylcholine receptor (mAChR) subtypes and identified the critical receptor sequences responsible for G protein specificity. Activation of a pertussis toxin insensitive G protein pathway, leading to a rapid and transient release of intracellular Ca2+ characteristic of the m3 receptor, could be specified by the transfer of as few as nine amino acids from the m3 to the m2 receptor. In a reciprocal manner, transfer of no more than 21 residues from the m2 to the m3 receptor was sufficient to specify activation of a pertussis toxin sensitive G protein coupled to a slow and oscillatory Ca2+ release pathway typical of the m2 subtype. Notably, these critical residues occur within the same region of the third cytoplasmic domain of functionally distinct mAChR subtypes.     

Location of a region of the muscarinic acetylcholine receptor involved in selective effector coupling

Chimaeric muscarinic acetylcholine receptors (mAChR) in which corresponding portions of mAChR I and mAChR II are replaced with each other have been produced in Xenopus oocytes by expression of cDNA constructs encoding them. Functional analysis of the chimaeric mAChRs indicates that a region mostly comprising the putative cytoplasmic portion between the proposed transmembrane segments V and VI is involved in selective coupling of mAChR I and mAChR II with different effector systems. In contrast, the exchange of this region between mAChR I and mAChR II does not significantly affect the antagonist binding properties of the two mAChR subtypes.     

MUSCARINIC ACETYLCHOLINE RECEPTOR SUBTYPE mRNAs IN THE HUMAN AND RAT VESTIBULAR PERIPHERY

The expression of the five muscarinic acetylcholine receptor (mAChR) subtypes (m1–m5) in the vestibular end-organs and in the primary afferent vestibular ganglia of the human and rat was studied using RT-PCR from the two tissue populations from both species. In the human, although all five mAChR subtypes were expressed in brain, only the m1, m2, and m5 mAChR subtypes were amplified from both the vestibular ganglia and the vestibular end-organs, while in the rat, all five mAChR subtypes were expressed. These data suggest that the efferent cholinergic axo-dendritic and axo-somatic synapses have a muscarinic component and that there are pharmacologic implications for patients with vestibular dysfunction.     

Motor discoordination in mutant mice lacking junctophilin type 3

Junctional complexes between the plasma membrane and endoplasmic reticulum (ER), often called "subsurface cisternae" or "peripheral coupling," are shared by excitable cells. These junctional membranes probably provide structural foundation for functional crosstalk between cell-surface and intracellular ionic channels. Our current studies have indicated that junctophilins (JPs) take part in the formation of junctional membrane complexes by spanning the ER membrane and interacting with the plasma membrane. Of the JP subtypes defined, JP type 3 (JP-3) is specifically expressed in neurons in the brain. It has been currently reported that triplet repeat expansions in the JP-3 gene are associated with Huntington's disease-like symptoms including motor disorder in human. To survey the physiological role of JP-3, we generated the knockout mice. The JP-3-knockout mice grew and reproduced normally, and we did not observe any morphological abnormality in the mutant brain. In the behavioral study, the mutant mice showed impaired performance specifically in balance/motor coordination tasks. Although obvious defects could not be observed in excitatory transmission among cerebellar neurons from the mutant mice, the data indicate that JP-3 plays an active role in certain neurons involved in motor coordination.     

Muscarinic acetylcholine receptor (mAChR) inhibitor from snake venom: interaction with subtypes of human mAChR.

Snake venoms can contain a variety of well-studied neurotoxins, especially nicotinic acetylcholine receptor inhibitor, normally called postsynaptic neurotoxin. Karlsson first reported muscarinic acetylcholine receptor (mAChR) inhibitor from snake venom. In a previous study in our laboratory, we found a mAChR inhibitor from Naja naja sputatrix venom that bound to rat brain synaptosomes. Brain synaptosomes contain all subtypes of mAChRs, and thus the exact selectivity of the inhibitor could not be determined. mAChR inhibitor from N. naja sputatrix venom was purified and the binding to all human mAChR subtypes (M1, M2, M3, M4, and M5) was investigated and is reported in this communication. The inhibitor bound to all subtypes of the human mAChR, but showed considerably high selectivity for the M5 subtype. It was also found that the reduction of disulfide bonds in the inhibitor eliminated the binding to the mAChR. This suggests that a specific tertiary conformation maintained by disulfide bonds is essential for binding to the mAChR. An oligo peptide, QIHDNCYNE, comparable to a part of the inhibitor molecule, was synthesized and studied for its binding to the mAChR. The synthetic peptide did not show any binding activity, suggesting this portion of the inhibitor molecule is not involved in mAChR binding. The selective binding of the M5 mAChR subtype to antagonists has not yet been reported. Therefore, the purified inhibitor reported in this communication may be a useful tool to clarify the mechanism of muscarinic cholinergic transmission.     

An allosteric potentiator of M4 mAChR modulates hippocampal synaptic transmission

Muscarinic acetylcholine receptors (mAChRs) provide viable targets for the treatment of multiple central nervous system disorders. We have used cheminformatics and medicinal chemistry to develop new, highly selective M4 allosteric potentiators. VU10010, the lead compound, potentiates the M4 response to acetylcholine 47-fold while having no activity at other mAChR subtypes. This compound binds to an allosteric site on the receptor and increases affinity for acetylcholine and coupling to G proteins. Whole-cell patch clamp recordings revealed that selective potentiation of M4 with VU10010 increases carbachol-induced depression of transmission at excitatory but not inhibitory synapses in the hippocampus. The effect was not mimicked by an inactive analog of VU10010 and was absent in M4 knockout mice. Selective regulation of excitatory transmission by M4 suggests that targeting of individual mAChR subtypes could be used to differentially regulate specific aspects of mAChR modulation of function in this important forebrain structure.     

Metabolic roles of the M3 muscarinic acetylcholine receptor studied with M3 receptor mutant mice: a review

The M(3) muscarinic acetylcholine (ACh) receptor (M(3) mAChR) is expressed in many central and peripheral tissues. It is a prototypic member of the superfamily of G protein-coupled receptors and preferentially activates G proteins of the G(q) family. Recent studies involving the use of newly generated mAChR mutant mice have revealed that the M(3) mAChR plays a key role in regulating many important metabolic functions. Phenotypic analyses of mutant mice that either selectively lacked or overexpressed M(3) receptors in pancreatic beta -cells indicated that beta -cell M(3) mAChRs are essential for maintaining proper insulin release and glucose homeostasis. The experimental data also suggested that strategies aimed at enhancing signaling through beta -cell M(3) mAChRs might be beneficial for the treatment of type 2 diabetes. Recent studies with whole body M(3) mAChR knockout mice showed that the absence of M(3) receptors protected mice against various forms of experimentally or genetically induced obesity and obesity-associated metabolic deficits. Under all experimental conditions tested, M(3) receptor-deficient mice showed greatly ameliorated impairments in glucose homeostasis and insulin sensitivity, reduced food intake, and a significant elevation in basal and total energy expenditure, most likely due to increased central sympathetic outflow and increased rate of fatty acid oxidation. These findings are of potential interest for the development of novel therapeutic approaches for the treatment of obesity and associated metabolic disorders.     

Site-directed mutagenesis of the m2 muscarinic acetylcholine receptor. Analysis of the role of N-glycosylation in receptor expression and function

The cardiac m2 muscarinic acetylcholine receptor (mAChR) is a sialoglycosylated transmembrane protein which has three potential sites for N-glycosylation (namely, Asn2, Asn3, and Asn6). To investigate the role of N-linked oligosaccharide(s) in the expression and function of the receptor, we constructed glycosylation-defective mutant receptor genes in which the three asparagine codons were substituted by codons for either aspartate (Asp2,3,6), lysine (Lys2,3,6), or glutamine (Gln2,3,6). The glycosylation-defective and wild-type receptor genes were stably expressed in Chinese hamster ovary cells. Binding experiments with the membrane-permeable radioligand [3H]quinuclidinyl-benzilate and the membrane-impermeable radioligand [3H]N-methylscopolamine revealed that the Asp2,3,6, Gln2,3,6, and wild-type receptors were located exclusively on the cell surface and expressed in similar numbers. The Lys2,3,6 mutant receptor was expressed at a relatively low level and was therefore not included in subsequent experiments. Wheat germ agglutinin-Sepharose chromatography and sodium dodecyl sulfate-urea polyacrylamide gel electrophoresis demonstrated that the wild-type receptor, but not the Asp2,3,6 and Gln2,3,6 mutant receptors were N-glycosylated. The Asp2,3,6 and Gln2,3,6 mutant receptors had the same affinities for mAChR ligands as wild-type receptors. The time courses for degradation of the Asp2,3,6, Gln2,3,6, and wild-type receptors were also similar. In vivo functional analysis of the ability of the glycosylation mutant receptors to inhibit forskolin-stimulated cAMP accumulation revealed that maximal inhibition of adenylate cyclase activity was similar in the mutant and wild-type receptors. The Asp2,3,6 mutant receptor had an unaltered IC50 value for carbachol while the IC50 value of the Gln2,3,6 mutant receptor was 2-fold higher than that of the wild-type receptor. These results indicate that N-glycosylation of the m2 mAChR is not required for cell surface localization or ligand binding and does not confer increased stability against receptor degradation. Furthermore, N-glycosylation of the m2 mAChR is not required for functional coupling of the m2 mAChR to inhibition of adenylate cyclase.     

The Cysteine Residue in the Carboxyl-Terminal Domain of the m2 Muscarinic Acetylcholine Receptor Is Not Required for Receptor-Mediated Inhibition of Adenylate Cyclase

Muscarinic acetylcholine receptors (mAChRs) share with many other receptors of the guanine nucleotide-binding protein-coupled receptor family a highly conserved cysteine residue in the putative cytoplasmic carboxyl-terminal region of the protein. Because elimination of this cysteine in the beta 2-adrenergic receptor has been reported to decrease functional responsiveness, we determined if this cysteine residue is essential for mAChR-effector coupling by replacing Cys457 of the m2 mAChR with glycine and expressing wild-type and mutant receptor in Chinese hamster ovary (CHO) cells. The mutant and wild-type receptors exhibited similar affinities for binding of muscarinic ligands. In addition, the mutation did not affect cell surface localization or receptor-mediated inhibition of adenylate cyclase. These results indicate that the cysteine residue in the carboxyl-terminal domain of the m2 mAChR is not required for ligand binding or mAChR-mediated inhibition of adenylate cyclase in CHO cells.     

Decreased Muscarinic Acetylcholine Receptor Number in the Central Nervous System of the Tottering (tg/tg) Mouse

The tottering mouse (tg/tg) is a single-locus mutant, phenotypically characterized by the development of epilepsy associated with distinct electroencephalographic abnormalities. Because of reported alterations in muscarinic receptor (mAChR) number in various seizure states, mAChR density was examined in discrete brain regions of tottering (tg/tg) and coisogenic wild-type (+/+) mice. Saturation binding experiments revealed a widespread decrease in membrane mAChR density in the CNS of adult tottering (tg/tg) mice as compared with age-matched control wild-type (+/+) mice. The decrease was most pronounced in the hippocampus, where tg/tg mice exhibited a 40-60% reduction in mAChR density with no change in the affinity of the receptor for antagonists or agonists. At postnatal day 10, before the reported onset of electroencephalographic abnormalities, 114 and 65% increases in mAChR density were observed in the tg/tg hippocampus and cortex, respectively. Following the development of seizure activity at postnatal day 22, mAChR density in the tg/tg hippocampus was reduced by 29%. No change in brain mAChR density was seen in adult heterozygotes (+/tg), which do not develop electroencephalographic or seizure abnormalities. These results indicate that the development of reduced mAChR number in the CNS of the tg/tg mouse is secondary to abnormal neuronal activity, providing further support for the hypothesis that membrane depolarization can cause a decrease in neuronal mAChR density.     

Dynamic control of glutamatergic synaptic input in the spinal cord by muscarinic receptor subtypes defined using knockout mice

Activation of muscarinic acetylcholine receptors (mAChRs) in the spinal cord inhibits pain transmission. At least three mAChR subtypes (M(2), M(3), and M(4)) are present in the spinal dorsal horn. However, it is not clear how each mAChR subtype contributes to the regulation of glutamatergic input to dorsal horn neurons. We recorded spontaneous excitatory postsynaptic currents (sEPSCs) from lamina II neurons in spinal cord slices from wild-type (WT) and mAChR subtype knock-out (KO) mice. The mAChR agonist oxotremorine-M increased the frequency of glutamatergic sEPSCs in 68.2% neurons from WT mice and decreased the sEPSC frequency in 21.2% neurons. Oxotremorine-M also increased the sEPSC frequency in ～50% neurons from M(3)-single KO and M(1)/M(3) double-KO mice. In addition, the M(3) antagonist J104129 did not block the stimulatory effect of oxotremorine-M in the majority of neurons from WT mice. Strikingly, in M(5)-single KO mice, oxotremorine-M increased sEPSCs in only 26.3% neurons, and J104129 abolished this effect. In M(2)/M(4) double-KO mice, but not M(2)- or M(4)-single KO mice, oxotremorine-M inhibited sEPSCs in significantly fewer neurons compared with WT mice, and blocking group II/III metabotropic glutamate receptors abolished this effect. The M(2)/M(4) antagonist himbacine either attenuated the inhibitory effect of oxotremorine-M or potentiated the stimulatory effect of oxotremorine-M in WT mice. Our study demonstrates that activation of the M(2) and M(4) receptor subtypes inhibits synaptic glutamate release to dorsal horn neurons. M(5) is the predominant receptor subtype that potentiates glutamatergic synaptic transmission in the spinal cord.     

Novel interaction between the M4 muscarinic acetylcholine receptor and elongation factor 1A2

The activation of the muscarinic acetylcholine receptor (mAChR) family, consisting of five subtypes (M1-M5), produces a variety of physiological effects throughout the central nervous system. However, the role of each individual subtype remains poorly understood. To further elucidate signal transduction pathways for specific subtypes, we used the most divergent portion of the subtypes, the intracellular third (i3) loop, as bait to identify interacting proteins. Using a brain pull-down assay, we identify elongation factor 1A2 (eEF1A2) as a specific binding partner to the i3 loop of M4, and not to M1 or M2. In addition, we demonstrate a direct interaction between these proteins. In the rat striatum, the M4 mAChR colocalizes with eEF1A2 in the soma and neuropil. In PC12 cells, endogenous eEF1A2 co-immunoprecipitates with the endogenous M4 mAChR, but not with the endogenous M1 mAChR. In our in vitro model, M4 dramatically accelerates nucleotide exchange of eEF1A2, a GTP-binding protein. This indicates the M4 mAChR is a guanine exchange factor for eEF1A2. eEF1A2 is an essential GTP-binding protein for protein synthesis. Thus, our data suggest a novel role for M4 in the regulation of protein synthesis through its interaction with eEF1A2.     

Structural determinants for the interactions between muscarinic toxin 7 and muscarinic acetylcholine receptors

Muscarinic acetylcholine receptors (mAChRs) have five subtypes and play crucial roles in various physiological functions and pathophysiological processes. Poor subtype specificity of mAChR modulators has been an obstacle to discover new therapeutic agents. Muscarinic toxin 7 (MT7) is a natural peptide toxin with high selectivity for the M1 receptor. With three to five residues substituted, M3, M4, and M5 receptor mutants could bind to MT7 at nanomolar concentration as the M1 receptor. However, the structural mechanisms explaining MT7–mAChRs binding are still largely unknown. In this study, we constructed 10 complex models of MT7 and each mAChR subtype or its mutant, performed molecular dynamics simulations, and calculated the binding energies to investigate the mechanisms. Our results suggested that the structural determinants for the interactions on mAChRs were composed of some critical residues located separately in the extracellular loops of mAChRs, such as Glu4.56, Leu4.60, Glu/Gln4.63, Tyr4.65, Glu/Asp6.67, and Trp7.35. The subtype specificity of MT7 was attributed to the non‐conserved residues at positions 4.56 and 6.67. These structural mechanisms could facilitate the discovery of novel mAChR modulators with high subtype specificity and enhance the understanding of the interactions between ligands and G‐protein‐coupled receptors. Copyright © 2015 John Wiley & Sons, Ltd.