Comparative properties of the in ovo and in vitro differentiation of the muscarinic cholinergic receptor in embryonic heart cells

Subtype-specific regulation of muscarinic receptor expression and function by heterologous receptor activation

Incubation of cultured embryonic chicken heart cells with the beta-adrenergic agonist isoproterenol resulted in a dose-dependent increase in the number of mAChR on the surface of intact cells. The isoproterenol-mediated increase in mAChR number was time dependent and reached a maximum by 48 h. Chick heart cells treated with isoproterenol exhibited a greater than 6-fold increase in the sensitivity for carbachol-mediated inhibition of adenylyl cyclase activity as compared to control. Stimulation of cultured heart cells for 24 h with isoproterenol resulted in a 25-35% increase in cm2 mRNA levels as compared to control cm2 mRNA levels. In contrast, the level of cm4 mRNA was not significantly affected by isoproterenol treatment. cm2 mRNA levels were maximally elevated by 15 h following isoproterenol stimulation and remained elevated for up to 72 h. Incubation of cells with isoproterenol in the presence of Rp-cAMP, an inhibitor of cAMP-dependent protein kinase, blocked the increase in the level of cm2 mRNA. Thus, prolonged activation of beta-adrenergic receptors results in an increase in mAChR number and muscarinic responsiveness in chick heart cells due to a cAMP-dependent protein kinase mediated increase in cm2 mRNA levels.

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.

Distribution pattern of acetylcholinesterase in early embryonic chicken hearts

To study the developmental appearance of acetylcholinesterase in early embryonic hearts, an enzyme-histochemical study was carried out in chicken embryos ranging from cardiogenic plate to late tubular stages. Initially acetylcholinesterase is present in all cells of the (future) myocardium. When 13-14 pairs of somites have developed, i.e., shortly before blood propulsion starts, acetylcholinesterase selectively disappears from the ventral and lateral wall of the developing ventricle. Slightly later, when 18-19 pairs of somites have developed, acetylcholinesterase also disappears from the dorsal and anterior wall of the atrium. High concentrations of acetylcholinesterase remain present in the outflow tract and lower concentrations in a continuous tract along the lesser curvature of the heart, the atrial side of the atrioventricular canal, and the left wall of the atrium. In late tubular stages of heart development, acetylcholinesterase is reexpressed in the inner myocardial layer of the ventricle, i.e., in the developing trabeculae and the ventricular side of the atrioventricular canal, where it is continuous with the acetylcholinesterase-expressing cells of the atrial side of the atrioventricular canal. The expression pattern of acetylcholinesterase in early embryonic chick hearts coincides with that of areas that control the conduction of the impulse and may reveal a cholinergic signal transduction system that is responsible for a coordinated contraction pattern of the myocardium prior to the development of the definitive conductive system.

Aging of rat heart myocytes disrupts muscarinic receptor coupling that leads to inhibition of cAMP accumulation and alters the pathway of muscarinic-stimulated phosphoinositide hydrolysis

The biochemical responses to muscarinic stimulation (inhibition of isoproterenol-stimulated cAMP accumulation and stimulation of phosphoinositide turnover) were investigated in intact myocyte cultures prepared from the hearts of newborn rats. The studies employed young (5 days after plating) and aged (14 days old) myocyte cultures. Aging of the myocyte cultures was accompanied by marked alterations in both the inhibition of cAMP accumulation and the stimulation of the phosphoinositide metabolism via the muscarinic receptors. However, the effects on the two muscarinic responses were different. The first response was disrupted at the level of the coupling of the muscarinic receptors with adenylate cyclase through Gi. On the other hand, muscarinic stimulation of phosphoinositide hydrolysis still occurred in the aged myocyte cultures; however, the inositol trisphosphate generated was not converted to inositol 1-phosphate as in young cultures or as in aged cultures stimulated by norepinephrine. This raises the possibility that muscarinic activation of aged myocyte cultures shifts the metabolic state of the cells and alters the pathway of phosphoinositide hydrolysis. Treatment of aging cultures with phosphatidylcholine liposomes under conditions that yielded aged myocyte cultures with a lipid composition resembling that of young ones restored the muscarinic effect on cAMP accumulation, where the impairment in aged cultures was at the coupling stage (which takes place in the plasma membrane). This treatment had no effect on the response of the phosphoinositide metabolism to muscarinic stimulation.

Hemodynamic effects of acetylcholine in the chick embryo and differences from those in the rat embryo

It has been reported that acetylcholine induces cardiac anomalies in the chick embryo. Thus, we studied hemodynamic effects of this drug in the chick embryo and also compared them with those in the rat embryo since we found that the effect of caffeine was different between the chick and rat embryos. Acetylcholine was given at doses of 5, 0.5, and 0.05 micrograms into the vitelline vein in chick embryos at Hamburger-Hamilton stage 21 and at a dose of 0.5 micrograms into the placenta in rat embryos at gestational day 12. In the chick embryo, heart rate was reduced to 91, 88, and 87% of control at the end of injection of 0.05, 0.5, and 5 micrograms, respectively, then returned to the baseline level. Vitelline arterial blood pressure was 110% of control with 0.05 micrograms, 134% with 0.5 micrograms, and 142% with 5 micrograms at 1 min after injection. The dorsal aortic blood flow decreased with time after injection, but it was increased only by a 5 micrograms dose at the end of injection. The vascular resistance increased in a dose-dependent manner. In the rat embryo, the change of heart rate was qualitatively similar to that of the chick embryo. The blood pressure did not change significantly. The blood flow velocity at the outflow tract decreased at the end of injection, which indicated the decrease in cardiac output, along with slowing of heart rate, then returned to the control level thereafter.(ABSTRACT TRUNCATED AT 250 WORDS)

Muscarinic acetylcholine receptors in the heart of rats before and after birth

Atropine-displaceable binding of (3H)quinuclidinyl benzilate (QNB) to homogenates was used to identify the muscarinic binding sites in rat heart atria and ventricles and to investigate developmental changes in their concentration and binding properties between the 15th day of prenatal life and 3 months after birth. On the 15th day of prenatal life, muscarinic binding sites were already present in the heart. Their concentration increased steeply between the 15th and 19th days of prenatal development; in the atria, it remained high until the 1st day after birth and thereafter it diminished throughout the postnatal life, while in the ventricles the decrease started before the first postnatal day. The concentration of the binding sites was 1.8-3.0 times higher in the atria than in the ventricles at all time points investigated. Their affinity for QNB (the antagonist) was the same in the atria and ventricles and did not change during postnatal development (KD of 17.8 pmol/l at an infinitely low concentration of the binding sites). The binding of carbamoylcholine (the agonist) to muscarinic binding sites was analysed in experiments with the displacement of (3H)QNB binding, assuming the presence of high- and low-affinity binding sites for agonists. The proportion between the concentrations of the two classes of agonist binding sites is close to 1:1 both in the atria and the ventricles and does not change with age. No statistical significant differences were discovered between the affinities of the high- and low-affinity binding sites for carbamoylcholine between the atria and the ventricles and between new-born and adult rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Assay of muscarinic acetylcholine receptor function in cultured cardiac cells by stimulation of 86Rb+ efflux

An assay for the increase in potassium permeability mediated by muscarinic acetylcholine receptors (mAChR) in cultured cardiac cells is described, using the K+ ion substitute 86Rb+ as the tracer ion. Cardiac cells accumulate 86Rb+ from the extracellular medium in a Na+/K+ ATPase-dependent manner. Subsequent efflux of 86Rb+ in the absence and presence of muscarinic agonists follows kinetics similar to those previously reported for 42K+. The mAChR agonist carbamylcholine (carbachol) stimulated 86Rb+ efflux with an EC50 of 50 nM. The half-time for efflux is reduced by greater than 40% at maximally effective concentrations of agonist. Stimulation of 86Rb+ efflux by carbachol is blocked by the mAChR antagonist atropine with an IC50 of 15 nM. The stimulation of 86Rb+ efflux by carbachol is not affected by the presence of the Na+/K+ ATPase inhibitor ouabain. This assay provides a method for quantitating the mAChR-mediated increase in K+ permeability in cardiac cells without the use of 42K+.

Ontogenesis of physiological responsiveness and guanine nucleotide sensitivity of cardiac muscarinic receptors during chick embryonic development

Atria isolated from 4-day chick embryos were much less responsive to the negative chronotropic effect of muscarinic agonists than were atria from 5- or 8-day embryos, even though the density of muscarinic acetylcholine receptors (mAChR) was similar at all these ages. The mAChR in hearts from 4-day embryos were also significantly less susceptible to regulation of receptor number by in vivo agonist treatment and required a 2-5-fold greater dose of the muscarinic agonist carbachol to achieve a decrease in receptor number equivalent to that observed in 5- or 8-day embryonic hearts. When 4-day atrial membranes were assayed in physiological buffers, agonist binding to the mAChR was not regulated by GTP unless a sulfhydryl reducing agent was present. Receptors from 5- and 8-day embryos did not require addition of a sulfhydryl reducing agent in order to see guanine nucleotide effects on agonist binding. Even in the presence of a sulfhydryl reducing agent, carbachol binding to the mAChR in 4-day membranes was much less sensitive to guanyl-5'-yl imidodiphosphate (GppNHp) than binding to mAChR in 5- or 8-day membranes. In addition, forskolin-activated adenylate cyclase activity was much less sensitive to inhibition by GppNHp in membranes from 4-day atria than from 5- and 8-day atria. The GTP-binding component (NI) which couples the mAChR to inhibition of adenylate cyclase activity was examined by covalent modification with pertussis toxin.(ABSTRACT TRUNCATED AT 250 WORDS)

Differentiation of receptor sites for [3H]nitrendipine in chick hearts and physiological relation to the slow Ca2+ channel and to excitation-contraction coupling

The properties of interaction of the Ca2+ channel antagonist [3H]nitrendipine have been investigated in chick hearts at various stages of in ovo and post-natal development and in cultured cells. The dissociation constant of the [3H]nitrendipine-receptor complex is between 0.4 nM and 0.5 nM for intact ventricle and cultured cells. [3H]Nitrendipine binding is antagonized by nitrendipine analogs. The order of efficacy of the different dihydropyridine molecules is nitrendipine greater than nimodipine greater than nifedipine greater than nisoldipine with Kd values ranging from 0.5 to 4 nM. Inhibition of [3H]nitrendipine binding by other antiarrhythmic molecules like amiodarone, F13004 and bepridil was observed. Half-maximum inhibitions (K0.5) were found for verapamil and D600 at concentrations between 0.23 and 0.26 microM. The potency of organic Ca2+ blockers to depress by 50% the maximum amplitude of spontaneous beating of heart cells is closely related to K0.5 values obtained from [3H]nitrendipine binding experiments. Electrophysiological results indicate that the slow channel is insensitive to nitrendipine at the younger stage of development (3-day-old) whereas, in adult like cells, nitrendipine (50 nM) abolished both slow action potential due to the slow Ca2+ channel and contraction. The maximum binding capacity for [3H]nitrendipine is found to increase during development of the embryonic heart from 40 fmol/mg protein at day 3 to 100 fmol/mg protein at day 14, to stay relatively stable until day 18. Then the number of sites increases rapidly to reach a second plateau at 210 fmol/mg protein on day 4 after hatching. Treatment with 6-hydroxydopamine results in 35% increase in [3H]nitrendipine binding, whereas reserpine treatment is without effect. Developmental properties of nitrendipine-sensitive Ca2+ channels have been compared with those of tetrodotoxin-sensitive Na+ channels and muscarinic receptors. These results indicate that nitrendipine receptors exist at the early stage of development (3-day-old-hearts) but that they do not correspond to functional slow Ca2+ channels, that in ovo development corresponds both to an increase of the number of [3H]nitrendipine receptors and to the transformation of silent Ca2+ channels into functional Ca2+ channels, and that there is a regulation of the level nitrendipine-sensitive Ca2+ channels by innervation.

Muscarinic receptors and responses in intact embryonic chick atrial and ventricular heart cells

We have studied muscarinic acetylcholine (ACh) receptors in intact atrial and ventricular heart cells dissociated from 8-day chick embryos and maintained in sparse cell cultures. Two specific antagonists, [3H]quinuclidinyl benzilate (QNB) and [3H]N-methyl scopolamine (NMS), bind to surface sites with high affinity (Kds congruent to 40 and 400 pM, respectively). The concentration of [3H]QNB sites in ventricular cell cultures (460 fmole/mg protein) was comparable to the concentration of sites in atrial cultures (420 fmole/mg protein). The same result was obtained with [3H]NMS. Autoradiography following incubation in saturating concentrations of [3H]QNB shows that nearly all of the atrial and ventricular myocytes were labeled and that the distribution of grains over individual cells was uniform. The mean binding site density was 109/micron2 for atrial cells and 117/micron2 for ventricular cells. In contrast to the antagonist binding results, microelectrode recordings from individual myocytes or from small clusters of cells showed that many more atrial myocytes (89%) were sensitive to 10(-4) M carbachol than were ventricular myocytes (26%). Saline extract of embryonic brain tissue added to the culture medium did not alter the number or distribution of ligand binding sites but it produced a 2.6-fold increase in the number of carbachol-sensitive ventricular cells.

Atropine-induced alterations of normal development of muscarinic receptors in the embryonic chick heart

The development of muscarinic acetylcholine receptors in chick heart was studied from incubation days 5 through 20. There is a parallel increase in receptor density in atrium and ventricle until the last half of incubation, when the atrial, but not the ventricular, receptor density increases. This increase is blocked by exposure to atropine on incubation days 11 through 14, but not on days 16 through 19. This specific regional increase is coincident with the appearance of functional cholinergic innervation of the heart. During this same period there is an alteration in muscarinic receptor binding properties in both atrium and ventricle that is characterized by an increase in the proportion of receptors displaying high affinity agonist binding. This increase is blocked in the atrium, but not the ventricle, by atropine exposure on incubation days 11 through 14. Thus, there is a critical period in the development of atrial muscarinic receptors during which the receptors are susceptible to modulation by exposure to an antagonist.

Normal serum and lipoprotein-deficient serum give different expressions of excitability, corresponding to different stages of differentiation, in chicken cardiac cells in culture

Monolayers of cardiac cells from 11-day-old chicken hearts have different properties when maintained in fetal calf serum or in a lipoprotein-deficient serum (LPDS). Cells in fetal calf serum have a resting potential near -60 mV; the rate of rise of the action potential is low (less than 10 V/sec); the action potential and the contraction are essentially unaffected by tetrodotoxin (TTX); and the beating properties are unaffected by muscarinic agents. Cells in LPDS have a resting potential near -75 mV, and a fast rise of the action potential (approximately equal to 100 V/sec) that is drastically decreased by TTX with a parallel abolition of contraction, and the beat is blocked by very low concentrations of muscarinic agonists. Cells that are physiologically fully responsive to TTX and to muscarinic agents have receptors that remain stable 24 hr after protein synthesis is blocked, whereas cells that are physiologically unresponsive to TTX and muscarinic agents have receptors that are rapidly degraded with half-lives between 9 hr (TTX receptor) and 14 hr (muscarinic receptor). Differences in the physiological and biochemical properties are accompanied by changes in the cholesterol contents of the cell membranes. The properties of cardiac cells cultured in normal serum are similar to those found for cells of chicken hearts in the very early embryonic stage, whereas those of cardiac cells cultured in LPDS correspond to the late embryonic stage.

Appearance and distribution "in situ" of nicotinic acetylcholine receptors in cervical myotomes of young chick embryos. Radioautographic studies by light and electron microscopy

Localization of the acetylcholine (nicotinic) receptor sites was investigated in the developing cervical myotomes of the early chick embryo by radioautography at the light and electron microscope level, using 125I-alpha-bungarotoxin. The presence of cholinergic receptor sites was detected in situ as early as 60 hours of incubation (stage 17); their relative density increased in the myotome during the differentiation of the somite. Specific labeling of these receptor sites was detected in the myotomal tissue but not in the notochord, spinal cord or periaxial mesenchyme. The distribution of the receptor sites was uniform in the myotome at 3 days in ovo. An anterior-posterior asymmetry of the density appeared at 4 days in ovo and developed up to the 6th day. The highest density of these toxin-binding receptor sites was observed near the spinal motor nerve bundle as revealed by silver staining. These observations, made in situ, are discussed with respect to the possible neurotrophic or physical effects of the early motor innervation.

Muscarinic acetylcholine receptors on culture glia cells

Muscarinic acetylcholine receptors (76 fmol/mg protein) were detected on cultured glia cells (astroblasts) from embryonic chicken brain by specific [3H]quinuclidinylbenzilate (QNB) binding at physiological conditions. The QNB binding (Kd = 9.5 x 10(-11)) to the intact cells seems to be cooperative (nH = 1.98) as shown by graphical methods.

Developmental properties of the fast Na+ channel in embryonic cardiac cells using neurotoxins

This paper describes how neurotoxins specific of the fast Na+ channel are used to study its differentiation in embryonic cardiac cells during heart ontogenesis. Structural and functional differentiation of the fast Na+ channel have been followed using both electrophysiological and biochemical techniques.

Differentiation of the fast Na+ channel in embryonic heart cells: interaction of the channel with neurotoxins

The sensitivity of embryonic cardiac cells to tetrodotoxin (TTX) increases with age. At the early embryonic stage, the maximum upstroke velocity is not affected by the presence of TTX. In the course of both in ovo and in vitro development, this velocity reaches an adult-like value of 90-120 V/sec, which is decreased in the presence of TTX to 5-10 V/sec. The differentiation of the Na+ channel has been followed by using three types of specific toxins: (i) TTX or a tritiated derivative of it, (ii) a polypeptide toxin extracted from sea anemone, and (iii) the alkaloidic toxins veratridine and batrachotoxin. Electrophysiological, including voltage-clamp experiments, and biochemical studies have shown (i) that the TTX receptor and the fast Na+ channel machinery exist even when action potentials are insensitive to TTX--the channel is then in a nonfunctional or silent form that is revealed (or chemically activated) by both the alkaloids and the polypeptide toxin--and (ii) that the total number of Na+ channels increases during development by a factor of 4 or 5. In monolayers of cardiac cells insensitive to TTX in which all Na+ channels are in a nonfunctional form, the rate of degradation of the TTX receptor follows first-order kinetics with a half-time of 9 hr. In aggregates fully sensitive to TTX, the number of TTX receptors remains perfectly stable 24 hr after blockade of protein synthesis.