Developmental expression of muscarinic acetylcholine receptors in chick retina: selective induction of M2 muscarinic receptor expression in ovo by a factor secreted by muller glial cells.

Muscarinic acetylcholine receptors (mAChRs) play an important role in signal processing in the retina. We have used subtype-specific antibodies to identify the changes in the localization of mAChR expression during embryonic development of the retina in vivo and their relationship to the changes in mAChRs in retinal cells in culture. We have demonstrated previously that treatment of fresh retinal cultures with conditioned media from mature retinal cultures specifically induces expression of the M(2) mAChR (McKinnon et al., 1998). We show that the M(2)-inducing activity, which we tentatively have called MARIA (muscarinic acetylcholine receptor-inducing activity) is produced by Müller glial cells in culture, because significant activity can be found in media conditioned by essentially neuron-free cultures of Müller glia, as well as by a Müller glial cell line but not several neuroblastoma cell lines. We also demonstrate that the appearance of the M(2) receptor in vivo occurs concomitantly with the appearance of significant numbers of Müller glial cells in the developing retina. Furthermore, the administration of crude or partially purified preparations of MARIA to developing chick embryos in ovo induces precocious expression of M(2) mAChRs in the appropriate cell types in the retina. These results show that a factor secreted by cultured retinal Müller glia can regulate M(2) mAChR expression in vivo and in vitro and suggest that the secretion of MARIA by Müller glia in vivo may be responsible for the normal induction of M(2) mAChR expression during embryonic development.

Molecular analysis of the regulation of muscarinic receptor expression and function.

We have investigated the molecular mechanisms involved in the regulation of muscarinic acetylcholine receptor gene expression and localization and generated knockout mice to study the role of the M1 muscarinic receptor in vivo. We have used the MDCK cell system to demonstrate that different subtypes of mAChR can be targeted to different regions of polarized cells. We have also examined the developmental regulation of mAChR expression in the chick retina. Early in development, the M4 receptor is the predominant mAChR while the levels of the M2 and M3 receptors increase later in development. The level of M2 receptor is also initially very low in retinal cultures and undergoes a dramatic increase over several days in vitro. The level of M2 receptor can be increased by a potentially novel, developmentally regulated, secreted factor produced by retinal cells. The promoter for the chick M2 receptor gene has been isolated and shown to contain a site for GATA-family transcription factors which is required for high level cardiac expression. The M2 promoter also contains sites which mediate induction of transcription in neural cells by neurally active cytokines. We have generated knockout mice lacking the M1 receptor and shown that these mice do not exhibit pilocarpine-induced seizures and muscarinic agonist-induced suppression of the M-current potassium channel in sympathetic neurons.

Molecular mechanisms for the regulation of the expression and function of muscarinic acetylcholine receptors.

The regulation of muscarinic acetylcholine receptor expression and function was investigated in cultured cells and in knockout mice. Muscarinic agonist exposure causes m2 receptor desensitization and sequestration and decreases the expression of cardiac potassium channels. The expression of m2 receptors in chick retina is regulated by a developmentally regulated secreted factor. Mice lacking the m1 receptor exhibit a loss of muscarinic regulation of M-current potassium channel activity and pilocarpine-induced seizures.

Identification and localization of muscarinic acetylcholine receptors in the ocular tissues of the chick.

The purpose of this study was to characterize the distribution of muscarinic acetylcholine receptors (mAChRs) in the ocular tissues of hatched chicks. In the chick, different isoforms of these receptors have been detected in the brain, heart, and retina, and mAChRs in ocular tissues have been implicated in the pathogenesis of form-deprivation myopia. However, the precise anatomical distribution of mAChRs within the retina, retinal pigment epithelium, choroid, ciliary body, and ciliary ganglion remains unknown. We used affinity-purified, type-specific antibodies directed to three different chick mAChR subtypes (cm2, cm3, and cm4) to detect receptor immunoreactivity in sections and extracts of these ocular tissues. We found cm2, cm3, and cm4 in the retina, retinal pigment epithelium, choroid, and ciliary body. Within the retina, cm2 was expressed in numerous amacrine and ganglion cells; cm3 was expressed in many bipolar cells and small subsets of amacrine cells; and cm4 was found in most, if not all, amacrine and ganglion cells. Each mAChR was localized to distinct strata within the inner plexiform layer that cumulatively form three broad bands that closely match previously described localizations of subtype-nonspecific muscarinic ligand binding. Only cm3 was detected in the outer plexiform layer, and only cm4 was detected in the ciliary ganglion. We propose that each mAChR subtype has unique functions in each ocular tissue.

Developmental regulation of the cm2 muscarinic acetylcholine receptor gene: selective induction by a secreted factor produced by embryonic chick retinal cells.

The expression of the cm2 muscarinic acetylcholine receptor gene increases dramatically in chick retina during embryonic development in vivo. A similar developmental increase in cm2 expression occurs in embryonic chick retinal cells in culture. Conditioned medium from mature, but not young, retinal cultures contains a secreted factor that causes a selective increase in expression of cm2, but not cm3 or cm4, receptors. The secreted factor has been partially purified from serum-free medium, is protease-sensitive, and has a molecular weight >10 kDa. The cm2-inducing factor stimulates expression of a cm2 promoter/luciferase reporter gene, demonstrating that the increase in cm2 expression is attributable to increased gene transcription. Incubation of retinal cells with 14 identified neurotrophic and growth factors did not increase cm2 expression, suggesting that a novel developmentally regulated secreted factor mediates the subtype-specific induction of the cm2 receptor gene in retina.

Regulation of muscarinic receptor expression and function in cultured cells and in knock-out mice.

We have investigated the molecular and cellular basis for the regulation of expression and function of the muscarinic acetylcholine receptors. Treatment of cultured chick cardiac cells with the agonist carbachol results in decreased levels of mRNA encoding the m2 and m4 receptors. Treatment of chick embryos in ovo with carbachol results in decreased levels of mRNA encoding the potassium channel subunits GIRK1 and GIRK4 as well as the m2 receptor. There are thus multiple pathways for the regulation of mAChR responsiveness by long-term agonist exposure. Immunoblot, immunoprecipitation, and solution hybridization analyses have been used to quantitate the regulation of mAChR expression in chick retina during embryonic development. The m4 receptor is the predominant subtype expressed early in development, while the expression of the m3 and m2 receptors increases later in development. A cAMP-regulated luciferase reporter gene has been used to demonstrate that the m2 and m4 receptors have distinct specificities for coupling to G-protein subtypes to mediate inhibition of adenylyl cyclase. This system has also been used to demonstrate that beta-arrestin1 and beta-adrenergic receptor kinase-1 act synergistically to promote receptor desensitization. We have isolated the promoter region for the chick m2 receptor gene, identified regions of the promoter required to drive high level expression in cardiac and neural cells, and have identified a region which confers sensitivity of gene expression to neurally active cytokines. Finally, in order to determine the role of individual receptor subtypes in muscarinic-mediated responses in vivo, we have used the method of targeted gene disruption by homologous recombination to generate mice deficient in the m1 receptor.

Tissue-specific regulation of muscarinic acetylcholine receptor expression during embryonic development.

We used solution hybridization, immunoprecipitation, and immunoblot analyses to examine the developmental expression of chicken m2 (cm2), cm3, and cm4 muscarinic acetylcholine receptor (mAChR) mRNA and protein in embryonic and post-hatched chick heart and retina in order to correlate developmental expression patterns with known physiological events. cm2 is the predominant mAChR subtype expressed in chick heart. cm3 and cm4 protein and mRNA expression is very low in chick heart, and cm3 expression is highest early in development. The decrease in cm3 expression correlates well with the developmental decrease in mAChR-mediated activation of phospholipase C. cm4 is the predominant mAChR subtype expressed in chick retina. The expression of both cm4 protein and mRNA is highest early in development and decreases as development progresses. cm2 and cm3 mAChR are expressed at approximately equivalent levels and have similar patterns of expression. The cm2 and cm3 protein levels increase throughout development, while cm2 and cm3 mRNA levels peak at embryonic day 15 and then decrease after hatching. Our data indicate that the three mAChR subtypes are differentially regulated in chick heart and retina and that the patterns of expression of mAChR may be important in the development and physiology of these tissues.

Molecular analysis of the regulation of muscarinic receptor expression and function.

Several systems are being used to determine the molecular and cellular basis for the regulation of expression and function of the muscarinic receptors. Treatment of chick heart cells in culture results in decreased levels of mRNA encoding the cm2 and cm4 receptors. This probably results from decreased gene transcription which requires concomitant mAChR-mediated inhibition of adenylyl cyclase and mAChR-mediated stimulation of phospholipase C. Site-directed mutagenesis was used to demonstrate that the single tyrosine residue in the carboxyl-terminal cytoplasmic tail of the m2 receptor is involved in agonist-induced down-regulation but not sequestration. Activation of heterologous receptors in chick heart cells can also regulate mAChR mRNA levels. A cAMP-regulated luciferase reporter gene, has been used to demonstrate that the m4 receptor preferentially couples to Gi alpha-2 or Go alpha over Gi alpha-1 or Gi alpha-3 to mediate inhibition of adenylyl cyclase activity. Finally, in order to determine the role of individual receptor subtypes in muscarinic-mediated responses in vivo, we are beginning to use the method of targeted gene disruption by homologous recombination to generate mice deficient in specific receptor subtypes.