Muscarinic cholinergic receptors in the rat caudate-putamen and olfactory tubercle belong predominantly to the m4 class: in situ hybridization and receptor autoradiography evidence

Distinct kinetic binding properties of N-[3H]-methylscopolamine afford differential labeling and localization of M1, M2, and M3 muscarinic receptor subtypes in primate brain

Three classes of muscarinic receptors in mammalian brain have been postulated on the basis of equilibrium and kinetic binding data. However, equilibrium binding assays alone have not permitted a clear demonstration of the localization of putative M1, M2, and M3 receptor subtypes in the brain because of the overlapping affinities of virtually all muscarinic antagonists. In the present study, the conditions for selective occupancy of the M1, M2, and M3 receptor subtypes in the brain of the rhesus monkey were based on the distinct kinetic and equilibrium binding properties of N-[3H]-methylscopolamine (NMS) at cloned m1-m4 muscarinic receptor subtypes expressed in A9L transfected cells. Quantitative autoradiography of the M1, M2, and M3 muscarinic receptor subtypes in the primate brain was performed according to the following strategy. The M1 (m1) receptor subtype was labeled directly with a non-saturating concentration of [3H]-pirenzepine. The M2 (m2) subtype was labeled by incubations consisting of short, two minute pulses of [3H]-NMS after a preincubation with 0.3 microM pirenzepine to occlude m1, m3, and m4 sites. Selective occupancy of the M3 (m3) receptor (subtype) was achieved by pre-incubation with 0.5 nM unlabeled NMS to partially occlude the m1, m2, and m4 sites, equilibrium with 0.5 nM [3H]-NMS, followed by a 60 minute tracer dissociation in the presence of 1 microM atropine. In vitro autoradiography demonstrated that the M1 receptor subtype was confined to forebrain structures. M1 receptors were prevalent throughout the cerebral cortical mantle, amygdala, hippocampus, and the striatum. Low to background levels of the M1 receptor subtype were measured over the thalamus, hypothalamus, and brainstem. The M2 subtype was widely distributed with elevated densities of binding sites seen over all primary sensory cortical areas, and within discrete thalamic, hypothalamic, and brainstem nuclei. The distribution of the M3 receptor subtype was largely coincident with the pattern of the M1 sites labeled by non-saturating concentrations of [3H]-pirenzepine with some notable exceptions. Within the cerebral cortical mantle, the M3 receptor exhibited an elevated gradient over the orbitofrontal gyrus and the temporal lobe. Within the striatum, the M3 subtype was elevated over the anterior and dorsal part of the caudate nucleus, while the M1 receptors were most prevalent over the ventromedial sector. Selective labeling of M3 receptors was seen over the medial division of the globus pallidus and within the substantia nigra pars reticulata. In contrast to the pattern of the M1 receptor subtype, M3 receptors were prevalent also over midline nuclei of the hypothalamus.(ABSTRACT TRUNCATED AT 400 WORDS)

Laminar expression of m1-, m3- and m4-muscarinic cholinergic receptor genes in the developing rat visual cortex using in situ hybridization histochemistry. Effect of monocular visual deprivation

The postnatal development of laminar pattern of m1-, m3- and m4-mRNA-muscarinic acetylcholine receptor subtypes in the visual cortex of both normally raised and monocularly deprived rats (one eyelid sutured at the age of 11 days) was studied using in situ hybridization histochemistry and computer-assisted image analysis. From birth until day 15 the level of m1-receptor transcript in layer II/III increases markedly as compared to deeper layers. From day 15 up to day 18 a transient bimodal pattern develops with peaks in layers II/III and VI. Already on day 35 a more homogeneous distribution of m1-receptor mRNA level is detectable persisting until adulthood. In contrast, the m3-receptor mRNA shows already at birth a bimodal distribution with peaks in layers II/III and VI. Further development until adulthood results in transient changes in the ratio of the mRNA levels in these layers. In the adult visual cortex a similar laminar pattern as at birth is observed. From day 1 up to day 10 a relative increase in the mRNA level of the m4-receptor in layers II to IV is observed. From day 10 until day 15 a bimodal distribution of receptor mRNA develops with peaks in layers III and VI which is similar to the adult stage. However, between days 18 and 35 a shift in the laminar receptor mRNA distribution occurs resulting in peaks in layers IV and VI. The labeling of the m5-receptor transcript in rat visual cortex was very weak and did not show any alteration with age. Unilateral eyelid closure from postnatal day 11 resulted in transient changes in the laminar distribution of m3- and m4-receptor mRNA between postnatal days 18 and 25, whereas the development of the laminar pattern of the m1-receptor mRNA was not affected regardless of the length of visual deprivation. The distinct laminar developmental pattern of mRNA muscarinic receptor subtypes in rat visual cortex suggests specific roles of the muscarinic receptor subtypes during the first weeks of postnatal maturation of visual function.

Muscarinic receptors--characterization, coupling and function

At least five muscarinic receptor genes have been cloned and expressed. Muscarinic receptors act via activation of G proteins: m1, m3 and m5 muscarinic receptors couple to stimulate phospholipase C, while m2 and m4 muscarinic receptors inhibit adenylyl cyclase. This review describes the localization, pharmacology and function of the five muscarinic receptor subtypes. The actions of muscarinic receptors on the heart, smooth muscle, glands and on neurons (both presynaptic and postsynaptic) in the autonomic nervous system and the central nervous system are analyzed in terms of subtypes, biochemical mechanisms and effects on ion channels, including K+ channels and Ca2+ channels.

A comparison of the regulatory properties of striatal and cortical adenylate cyclase

Biochemical properties of adenylate cyclase in striatal and cortical membranes have been analyzed in parallel with their regulation by cholinergic compounds. Striatal adenylate cyclase is more sensitive to forskolin, while the cortical enzyme is more stimulated by GTP. In the presence of GTP, more inhibition by acetylcholine is seen in the cortex than in the striatum. Acetylcholine inhibits striatal adenylate cyclase activity equally in the presence or absence of forskolin but has a diminished ability to inhibit forskolin-stimulated adenylate cyclase in the cortex. The greater sensitivity of cortical muscarinic receptor-coupled adenylate cyclase to EGTA and calcium indicates predominant involvement of the calcium/calmodulin-dependent subtype of the enzyme. The relative effectiveness of antagonists, demonstrating an order of potency of atropine > amitriptyline > pirenzepine > gallamine in reversing the inhibition of adenylate cyclase by acetylcholine for both brain regions, suggests predominantly m4 receptor-mediated responses. These results suggest an m4-type receptor may be coupled to subtypes of adenylate cyclase in the striatum and cortex which differ in their biochemical properties.

Immunological localization of m1-m5 muscarinic acetylcholine receptors in peripheral tissues and brain

Knowledge of the distributions and functions of native m1-m5 muscarinic acetylcholine receptors in tissues is limited. To characterize the family of m1-m5 proteins directly, a panel of subtype-selective antibodies was generated against divergent i3 loop-fusion proteins. Each antibody was shown to bind a single cloned receptor specifically. In peripheral tissues and brain, four receptor proteins (m1-m4) were found to account for the vast majority of the muscarinic binding sites using immunoprecipitation studies with the subtype-specific antibodies. The subtypes were differentially distributed, although most tissues were comprised of a complex mixture of receptors. Moreover, within tissues there were major differences in the precise localization of the subtypes, as determined by immunocytochemistry. The immunological methods described offer a novel approach with exquisite sensitivity and specificity for delineating the distribution of m1-m5 receptors in animal and human tissues.

Modification of muscarinic acetylcholine receptors in the rat brain following chronic immobilization stress: an autoradiographic study

The modifications of rat brain muscarinic acetylcholine receptors induced by chronic immobilization stress lasting 10 min/daily or 2 h/daily for 3, 7 or 21 days were analyzed by quantitative in vitro autoradiography. [3H]N-Methylscopolamine ([3H]NMS) was used as ligand. Chronic immobilization stress for 10 min/day did not produce any significant change in the properties of [3H]NMS binding sites throughout the rat brain. In contrast, 2 h/day immobilization caused a significant increase in the maximal number of muscarinic receptors (Bmax) in several brain areas such as the cortical layers, the CA1 field of the hippocampus and caudate-putamen, among others. Affinity values (Kd) were not modified. These results suggest that chronic immobilization stress induces supersensitivity of muscarinic receptors in certain cholinergic pathways in rat brain, the pattern of response being different to that previously found for acute stress.

Kinetics of the functional loss of different muscarinic receptor isoforms in Xenopus oocytes

Native Xenopus oocytes express two isoforms of muscarinic receptors that mediate qualitatively different physiological responses. Oocytes of the majority of donors (common) express M3-like receptors (M3Rs) at comparable densities at both the animal and vegetal hemispheres of the cell. Rare (variant) donors possess oocytes that express mainly M1-like receptors (M1Rs), localized predominantly at the animal hemisphere. We have investigated the apparent degradation of these two isoforms and its relationship to their hemispheric distribution. Cycloheximide (CHX) caused a time-dependent decrease in receptor-mediated responses and [3H]quinuclidinyl benzylate (QNB) binding in oocytes from both types of donors. The t1/2 values ranged between 3 and 7 h. Removal of CHX resulted in rapid recovery of the response. This implied rapid degradation and turnover of both types of receptors. The loss of M1Rs was more than that of M3Rs. Moreover, the decrease was more rapid and more extensive on the animal hemisphere in both types of donors. Injection of oocytes expressing either receptor isoform with specific antisense oligonucleotides complementary to either m1 or m3 muscarinic receptors (from mouse) showed receptor loss at approximately the same rate as that calculated from experiments with CHX. Furthermore, oocytes of variant donors express M1Rs exclusively on the animal hemisphere, while the residual activity found on the vegetal hemisphere of the cell was mediated by M3Rs. Inhibition of putative receptor glycosylation with tunicamycin caused a rapid decrease in receptor-mediated responses and radioligand binding on M1Rs, but had virtually no effect on M3Rs. The expression of cloned m1 muscarinic receptors, however, was not affected by tunicamycin, suggesting that glycosylation is not a general prerequisite for the functional expression of muscarinic receptors.

Characterization and autoradiographic distribution of [3H]AF-DX 384 binding to putative muscarinic M2 receptors in the rat brain

The novel radioligand [3H]AF-DX 384 binds specifically and saturably to putative muscarinic M2 receptor sites in homogenates of rat cerebral cortex. In saturation studies, [3H]AF-DX 384 appears to bind to two subpopulations of sites/states, one of high affinity (Kd1 = 0.28 +/- 0.08 nM) and another of low affinity (Kd2 = 28.0 +/- 5.0 nM). The maximal binding capacity (Bmax) of [3H]AF-DX 384 binding sites represented 9.7 +/- 2.3 fmol/mg protein (Bmax1) and 1993 +/- 551 fmol/mg protein (Bmax2) for the high and low affinity sites/states, respectively. The ligand selectivity profile of [3H]AF-DX 384 (at 2 nM) revealed that (-)-quinuclidinyl benzylate = atropine greater than 4-diphenylacetoxy-N-methylpiperidine methobromide greater than AQ-RA 741 greater than AF-DX 384 greater than UH-AH 371 much greater than methoctramine greater than oxotremorine-M greater than hexahydro-sila-defenidol much greater than pirenzepine greater than carbamylcholine much much greater than nicotine. This suggests that under our assay conditions [3H]AF-DX 384 binds mostly to M2-like muscarinic receptors in the rat central nervous system. This is further supported by the clear M2-like pattern of distribution observed using quantitative receptor autoradiography. High densities of specific labelling were seen in areas such as the hypoglossal nucleus, the pontine nucleus, the superior colliculus, the motor trigeminal nucleus, various thalamic nuclei and certain cortical laminae. Compared to [3H]AF-DX 116, the percentage of specific binding detected with [3H]AF-DX 384 was much higher. This is likely to be related to the greater chemical stability and affinity of [3H]AF-EX 384. In addition, autoradiograms obtained with [3H]AF-DX 384 (2 nM) are of better quality with film exposure periods five shorter than those needed for [3H]AF-DX 116 (10 nM). Therefore, [3H]AF-DX 384 displays a good selectivity for muscarinic M2 sites and offers major advantages, including higher affinity and greater stability, over previously used ligands.

Muscarinic M2-selective ligands also recognize M4 receptors in the rat brain: evidence from combined in situ hybridization and receptor autoradiography

We have used autoradiographic techniques to examine the characteristics and distribution of the binding of reported selective M2 muscarinic ligands and compared them with the distribution of cells expressing mRNAs for the different subtypes of muscarinic receptors. Our results suggest that the M2 ligands used in the present study ([3H]OXO-M, ([3H]OXO-M,[3H]AF-DX384,AF-DX116, methoctramine) also recognize M4 receptors present in regions such as the striatum and olfactory tubercle. This is supported by 1) relative abundances of the different transcripts, with m2 mRNA being very scarce and m4 mRNA very abundant in these regions; 2) comparison of the pharmacological characteristics of M2-ligand binding sites in brain areas selected by their exclusive expression of M2 receptors versus areas enriched in M4 receptors. An important conclusion of these studies is that none of the muscarinic radioligands available at the present time appears to label specifically a single muscarinic receptor subtype population. Areas are suggested where autoradiographic techniques can be helpful in elucidating the subtype selectivity of existing and new ligands.

Affinity changes in muscarinic acetylcholine receptors in the rat brain following acute immobilization stress: an autoradiographic study

The modifications in rat brain muscarinic acetylcholine receptors induced by acute immobilization stress lasting 10 min or 2 h were analyzed by quantitative in vitro autoradiography. [3H]N-Methylscopolamine ([3H]NMS) was used as a ligand. Immobilization stress for 10 min did not produce any significant change in the properties of [3H]NMS binding sites throughout the brain. In contrast, 2 h immobilization caused a significant increase in receptor affinity (Kd) without modification in the maximal number of receptors (Bmax) in several brain areas such as the caudate-putamen, cortical layers and CA1 field of the hippocampus, among others. These results, found even in animals killed immediately after the end of the immobilization sessions, suggest that immobilization stress induces supersensitivity of muscarinic receptors in certain cholinergic pathways in rat brain.

Muscarinic M2 receptor mRNA expression and receptor binding in cholinergic and non-cholinergic cells in the rat brain: a correlative study using in situ hybridization histochemistry and receptor autoradiography

The goal of the present study was to identify the cells containing mRNA coding for the m2 subtype of muscarinic cholinergic receptors in the rat brain. In situ hybridization histochemistry was used, with oligonucleotides as hybridization probes. The distribution of cholinergic cells was examined in consecutive sections with probes complementary to choline acetyltransferase mRNA. Furthermore, the microscopic distribution of muscarinic cholinergic binding sites was examined with a non-selective ligand ([3H]N-methylscopolamine) and with ligands proposed to be M1-selective ([3H]pirenzepine) or M2-selective ([3H]oxotremorine-M). The majority of choline acetyltransferase mRNA-rich (i.e. cholinergic) cell groups (medial septum-diagonal band complex, nucleus basalis, pedunculopontine and laterodorsal tegmental nuclei, nucleus parabigeminalis, several motor nuclei of the brainstem, motoneurons of the spinal cord), also contained m2 mRNA, strongly suggesting that at least a fraction of these receptors may be presynaptic autoreceptors. A few groups of cholinergic cells were an exception to this fact: the medial habenula and some cranial nerve nuclei (principal oculomotor, trochlear, abducens, dorsal motor nucleus of the vagus). Furthermore, m2 mRNA was not restricted to cholinergic cells but was also present in many other cells throughout the rat brain. The distribution of m2 mRNA was in good, although not complete, agreement with that of binding sites for the M2 preferential agonist [3H]oxotremorine-M, but not with [3H]pirenzepine binding sites. Regions where the presence of [3H]oxotremorine-M binding sites was not correlated with that of m2 mRNA are the caudate-putamen, nucleus accumbens, olfactory tubercle and islands of Calleja. The present results strongly suggest that the M2 receptor is expressed by a majority of cholinergic cells, where it probably plays a role as autoreceptor. However, many non-cholinergic neurons also express this receptor, which would be, presumably, postsynaptically located. Finally, comparison between the distribution of m2 mRNA and that of the proposed M2-selective ligand [3H]oxotremorine-M indicates that this ligand, in addition to M2 receptors, may also recognize in certain brain areas other muscarinic receptor populations, particularly M4.

Heterogeneous binding of [3H]4-DAMP to muscarinic cholinergic sites in the rat brain: evidence from membrane binding and autoradiographic studies

The present study shows that [3H]4-DAMP binds specifically, saturably, and with high affinity to muscarinic receptor sites in the rat brain. In homogenates of hippocampus, cerebral cortex, striatum, and thalamus, [3H]4-DAMP appears to bind two sub-populations of muscarinic sites: one class of high-affinity, low capacity sites (Kd less than 1 nM; Bmax = 45-152 fmol/mg protein) and a second class of lower-affinity, high capacity sites (Kd greater than 50 nM; Bmax = 263-929 fmol/mg protein). In cerebellar homogenates, the Bmax of [3H]4-DAMP binding sites was 20 +/- 2 and 141 +/- 21 fmol/mg protein for the high- and the lower-affinity site, respectively. The ligand selectivity profile for [3H]4-DAMP binding to its sites was similar for both the high- and lower-affinity sites; atropine = (-)QNB = 4-DAMP much greater than pirenzepine greater than AF-DX 116, although pirenzepine was more potent (16-fold) at the lower- than at the high-affinity sites. The autoradiographic distribution of [3H]4-DAMP sites revealed a discrete pattern of labeling in the rat brain, with the highest densities of [3H]4-DAMP sites present in the CA1 sub-field of Ammon's horn of the hippocampus, the dentate gyrus, the olfactory tubercle, the external plexiform layer of the olfactory bulb and layers I-II of the frontoparietal cortex. Although the distribution of [3H]pirenzepine sites was similar to that of [3H]4-DAMP sites in many brain regions, significant distinctions were apparent. Thus, both the ligand selectivity pattern of [3H]4-DAMP binding and the autoradiographic distribution of sites suggest that although the high-affinity [3H]4-DAMP sites may consist primarily of muscarinic-M3 receptors, the lower-affinity [3H]4-DAMP sites may be composed of a large proportion of muscarinic-M1 receptors.

Recent trends in receptor analysis techniques and instrumentation

Receptor autoradiography allows visualization of receptor binding sites at the regional or light microscopic level. Receptor autoradiography is a mature methodology, in widespread use. It is also a dynamic and expanding methodology, benefiting constantly from the introduction of new techniques and instrumentation. In particular, receptor autoradiography has taken advantage of image analysis instrumentation to provide efficient spatial mapping of receptor populations and their pharmacological characteristics. A major contribution to the understanding of receptors has come from the recent cloning of the genes coding for many of these receptors. This has allowed the use of in situ hybridization to demonstrate the cells expressing mRNA coding for specific receptor subtypes. The result is that many receptor populations, previously thought to be homogeneous, are shown to be composed of several subtypes. As a consequence, the distribution of many receptors requires re-examination, which is aided by the development of new and more selective ligands. With the incorporation of techniques from molecular biology into receptor autoradiography, the demands upon image analysis instruments have expanded. Over the past decade, densitometric image analysers have attained a high level of sophistication for classical receptor autoradiography. However, to serve the needs of today's receptor laboratory, an image analyser must be equally capable in regional densitometry, in counting and spatial mapping of grain and/or cell locations at the microscopic level, and in analysing electrophoresis gels. Advances in image analysis hardware and software are keeping pace with the requirements of receptor laboratories.