Difference in the expression of asymmetric acetylcholinesterase molecular forms during myogenesis in early avian dermomyotomes and limb buds in ovo and in vitro

The A12 (asymmetric) form of acetylcholinesterase (AChE) is generally considered to be synthesized in leg muscle tissues by myotubes under neural influence, but not by myoblasts. We have examined the expression of the different molecular forms of AChE in explants of developing limb buds and dermomyotomes (the myogenic part of the somites) obtained from 3-day-old chick and quail embryos, either directly after removal or during in vitro culture. We describe a muscular differentiation of both territories in vitro, leading to the formation of myotubes which are morphologically similar to the class of early muscle cells described by Bonner and Hauschka (1974). In vivo the A12 form is present in quail dermomyotomes which are almost entirely composed of mononucleated poorly differentiated cells; in contrast, it is absent from similar cells in chick dermomyotomes and from limb buds in both species. This shows that in the case of quail embryos the appearance of the A12 form precedes the fusion of myoblasts into myotubes. In both species, dermomyotome explants express asymmetric and globular forms of the enzyme during muscular differentiation in vitro, whereas limb buds synthesize only globular forms. After surgical removal of neural tube and/or neural crest at 2 days in ovo, the biosynthesis of the A forms in quail dermomyotomes is not suppressed and is consequently not dependent upon prior connection of the dermomyotomes to central neurons or upon the presence of autonomic precursors. Since limb bud muscle cells derive from somites our results raise questions concerning the differentiation of migrating somitic cells in this territory where a neural influence appears necessary to induce the biosynthesis of asymmetric AChE forms.     

Ultracytochemical study on in vitro differentiation of neural retinal cells of chick embryos

In order to study cell differentiation and morphogenesis of neural retina, ultracytochemical examination for acetylcholine esterase (AChE) was carried out on neural retinal cells from 6-day-old chick embryos cultured in monolayer for 20 days. AChE is a suitable marker for identifying cell specificity and structure of cultured neural retinal cells, because its specific localization in the intact chick neural retina has been established. After about 2 weeks of culturing a number of cell aggregates formed on the monolayer sheet of glial cells, in which cell bodies were generally located on the periphery regions while their cellular processes were in the center, forming neuropil structures. Among such peripherally located cells presumptive ganglion, amacrine, bipolar, and photoreceptor cells could be distinguished. In the neuropil structures, some cellular processes had typical ribbon synapses indicating that these structures correspond to the plexiform layers of the retina. We could also classify the neuropils into two types of both from the AChE activity and from the structure of the nerve terminals. These findings indicate that our cell culture system can be used for the study of cell differentiation and histogenesis of retinal cells.     

Proliferating ability,morphological development and acetylcholinesterase activity of the neural tube cells in early chick embryos

Summary Using ³H-thymidine autoradiography and AChE histochemistry at the electron microscopic level on the same sections, the interrelationships between loss of proliferating ability, morphological development and increase of AChE activity during the course of differentiation of the neural tube cells were investigated in early chick embryos. The neural tube wall consisted of spindle-shaped cells with no AChE activity, weakly positive spindle-shaped cells showing AChE activity in the cisternae of the nuclear envelope and in a few short profiles of r-ER, moderately positive spindle-shaped cells showing AChE activity in the nuclear envelope and in a moderate number of r-ER profiles and intensely positive large round cells showing AChE activity in the nuclear envelope and in a large number of r-ER profiles. Nuclei of the AChE-negative, weakly positive and moderately positive cells were located in the ependymal layer (matrix). The AChE-intensely positive cells were in the mantle layer. The AChE-negative and weakly positive cells were capable of proliferation and were regarded as undifferentiated neuroepithelial cells. In contrast, the moderately positive and intensely positive cells were no longer capable of proliferation and were considered to be neurons. These findings indicate that the r-ER increases rapidly in amount and volume in newly formed neurons soon after their final cell division, and that AChE increases in the neurons in parallel to the development of the r-ER.     

Requirement of cell division for muscle actin expression in the primary muscle cell lineage of ascidian embryos

The role of cell division in the expression of muscle actin and its relationship to acetylcholinesterase (AChE) development was examined in cleavage-arrested embryos of the ascidian Styela. Muscle actin expression was detected by two-dimensional gel electrophoresis of radioactively labelled proteins and by in situ hybridization with a cDNA probe, whereas AChE activity was assayed by enzyme histochemistry. In the majority of cases, muscle actin expression was first detected in embryos arrested after the 16-cell stage. Some embryos showed muscle actin expression after arrest at the 8-cell stage, however, muscle actin mRNA did not accumulate in embryos arrested at earlier cleavages. The cells that expressed muscle actin in 8- to 64-cell cleavage-arrested embryos belonged to the primary muscle lineage; secondary muscle cell precursors did not express muscle actin. Zygotic muscle actin mRNA appeared to accumulate with myoplasmic pigment granules in the perinuclear region of cleavage-arrested embryos, suggesting that the myoplasm may have a role in the organization of muscle cells. In contrast to muscle actin, AChE was detected in a small proportion of embryos treated with cytochalasin as early as the 1- or 2-cell stage, and most embryos treated with cytochalasin at later cleavages expressed this enzyme in some of their cells. Most primary muscle lineage cells expressed both muscle actin mRNA and AChE, however, some cells expressed only muscle actin mRNA or AChE. The results suggest that at least three cleavages are required for muscle actin expression and that muscle actin and AChE expression can be uncoupled in cleavage-arrested embryos.     

Recovery of acetylcholinesterase activity in the axolotl embryo following inhibition with the organophosphorus inhibitor Gd-7

The restoration of acetylcholinesterase (AChE) activity in axolotl Ambystoma mexicanum embryo after treatment at 38-42 stages with irreversibly AChE-inhibiting Gd-7 phosphororganic inhibitor in concentrations, significantly decreasing AChE activity level, but not interfering with ontogenesis has been studied. The rate of AChE activity restoration in Gd-7 treated axolotl embryo depends on the level of the enzyme restraint and the stage of the embryo development. The value of maximal restoration of AChE activity differs; it is less in embryos, treated with Gd-7 at later stages of development. The ability of the embryos to swim restores parallel to the increase in AChE activity. The data obtained suggest that axolotl embryo possess compensatory mechanism for increasing AChE biosynthesis after decrease in its activity caused by Gd-7. Acetylcholine, accumulating in the organism at partial inactivation of AChE by phosphororganic inhibitor may participate in this mechanism.     

Recovery of acetylcholinesterase activity after irreversible inhibition by organophosphorous compounds in embryonic development

1. Recovery of acetylcholinesterase (AChE) activity was studied using the embryos of sea urchins Strongylocentrotus intermedius and S. nudus, embryos of axolotl Ambystoma mexicanum and in the chick embryo muscle culture treated by "irreversible" organophosphorous inhibitors (OPI). 2. AChE activity was assayed by a modified Ellman's procedure. 3. It follows from the data obtained that, unlike the plutei of sea urchins and the monolayer culture of chick embryo muscle cells, the embryos of axolotl show a compensatory increase in AChE biosynthesis after inhibition by OPI. 4. This mechanism is assumed to be related to the presence of a well developed neuromuscular system in the A. mexicanum embryos. 5. It is possible that acetylcholine accumulated as a result of partial AChE inhibition is responsible for the compensatory increase in AChE biosynthesis.     

The cholinergic system in the early development of chickens. 1. Choline acetyltransferase and acetylcholinesterase as the key regulators of acetylcholine metabolism

Acetylcholine esterase (AChE, EC 3.1.1.7) and choline acetyltransferase (CAT, EC 2.3.1.6) activities were studied in the early chick embryos. Gastrulation is accompanied by a sharp increase in the AChE activity which was most pronounced in anterior hypoblast. Three molecular of AChE (4.7, 6.8 and 10.9 S) were identified in the extract of chick embryos using a sucrose density gradient centrifugation. The CAT activity remained unchanged during gastrulation but increased twice at the end of gastrulation.     

Overexpressed Monomeric Human Acetylcholinesterase Induces Subtle Ultrastructural Modifications in Developing Neuromuscular Junctions of Xenopus laevis Embryos

Abstract: Formation of a functional neuromuscular junction (NMJ) involves the biosynthesis and transport of numerous muscle-specific proteins, among them the acetylcholine-hydrolyzing enzyme acetylcholinesterase (AChE). To study the mechanisms underlying this process, we have expressed DMA encoding human AChE downstream of the cytomegalovirus promoter in oocytes and developing embryos of Xenopus laevis. Recombinant human AChE (rHAChE) produced in Xenopus was biochemically and immunochemically indistinguishable from native human AChE but clearly distinguished from the endogenous frog enzyme. In microinjected embryos, high levels of catalytically active rHAChE induced a transient state of over-expression that persisted for at least 4 days postfertilization. rHAChE appeared exclusively as nonassembled monomers in embryos at times when endogenous Xenopus AChE displayed complex oligomeric assembly. Nonetheless, cell-associated rHAChE accumulated in myotomes of 2-and 3-day-old embryos within the same sub-cellular compartments as native Xenopus AChE. NMJs from 3-day-old DNA-injected embryos displayed fourfold or greater overexpression of AChE, a 30% increase in postsynaptic membrane length, and increased folding of the postsynaptic membrane. These findings indicate that an evolutionarily conserved property directs the intracellular trafficking and synaptic targeting of AChE in muscle and support a role for AChE in vertebrate synaptogenesis.     

Cholinergic traits in the neural crest: Acetylcholinesterase in crest cells of the chick embryo

Previous work by our group has demonstrated that mesencephalic neural crest cells at an early stage of migration are able to synthesize acetylcholine (ACh). Acetylcholinesterase (AChE), the enzyme responsible for ACh degradation, was examined in neural crest cells of the chick embryo, using cytochemical and biochemical methods. Observations at the light microscope level showed that cholinesterase activity, identified as true AChE, was present at all axial levels in presumptive crest cells of the neural folds, soon after closure of the neural tube. Subsequently, AChE activity was found in cells of the individualized neural crest and in crest cells migrating at cephalic and trunk levels. Cell counts revealed that 88–94% of the total crest population was AChE-positive. Electron microscope observations indicated that the enzyme was confined to perinuclear and endoplasmic reticulum cisternae. The AChE of migrating mesencephalic neural crest cells was identified as the dimeric form (sedimentation coefficient 6.9 S) of the catalytic subunit. These results indicate that the specific AChE is present in the majority of neural crest cells all along the neural axis. Thus the ability to synthesize and degrade ACh is expressed at least in some neural crest cells at an early stage of development.     

Comparison of the Molecular Forms of the Cholinesterases in Tissues of Normal and Dystrophic Chickens

Abstract: The levels and molecular forms of acetylcholinesterase (AChE, EC 3.1.1.7) and pseudocholinesterase (ΦChE, EC 3.1.1.8) were examined in various skeletal muscles, cardiac muscles, and neural tissues from normal and dystrophic chickens. The relative amount of the heavy (H_c) form of AChE in mixed-fibre-type twitch muscles varies in proportion to the percentage of glycolytic fast-twitch fibres. Conversely, muscles with higher levels of oxidative fibres (i.e., slow-tonic, oxidative-glycolytic fast-twitch, or oxidative slow-twitch) have higher proportions of the light (L) form of AChE. The effects of dystrophy on AChE and ΦChE are more severe in muscles richer in glycolytic fast-twitch fibres (e.g., pectoral or posterior latissimus dorsi, PLD); there is no alteration of AChE or ΦChE in a slow-tonic muscle. In the pectoral or PLD muscles from older dystrophic chickens, however, the AChE forms revert to a normal distribution while the ΦChE pattern remains abnormal. Muscle ΦChE is sensitive to collagenase in a similar way as is AChE, thus apparently having a similar tailed structure. Unlike skeletal muscle, cardiac muscle has very high levels of ΦChE, present mainly as the L form; AChE is present mainly as the medium (M) form, with smaller amounts of L and H_c. The latter pattern of AChE forms resembles that seen in several neural tissues examined. No alterations in AChE or ΦChE were found in cardiac or neural tissues from dystrophic chickens.     

Effects of the organophosphate insecticides diazinon and parathion on bobwhite quail embryos: skeletal defects and acetylcholinesterase activity

Bobwhite quail eggs were injected at 48 or 72 hr of incubation with various doses of the organophosphate (OP) insecticides diazinon or parathion and the embryos were examined after an additional 48 hr of incubation by both histological and cartilage-staining methods. Bobwhite embryos did not display the notochordal folding or vascular enlargement reported for OP-injected chicken embryos. Cartilage staining of embryos injected with insecticide at 72 hr of incubation and recovered at day 12 of incubation revealed severe shortening and contortion of the vertebral axis, as well as tibiotarsal, rib, and sternum defects. Parathion was more potent in causing skeletal defects than diazinon. No type I defects (micromelia, parrot beak) were detected. Radiometric acetylcholinesterase (AChE) assays of whole embryo homogenates were performed for day 6, 9, and 12 diazinon-injected and control embryos. Diazinon effected drastic reductions in AChE activity. Although the AChE and axial skeletal responses of bobwhite embryos to OP injection are similar to those reported in the literature for other species, some major differences in the bobwhite response were noted: namely, the absence of notochordal folding in the young bobwhite embryo and the absence of type I defects at day 12. These differences suggest that further studies with the bobwhite quail would be useful in clarifying the mechanisms involved in OP-induced teratogenesis.     

An evolutionary change in the muscle lineage of an anural ascidian embryo is restored by interspecific hybridization with a urodele ascidian

Anural ascidians do not develop into a conventional tailed larva with differentiated muscle cells, however, embryos of some anural ascidian species retain the ability to express acetylcholinesterase (AChE) in a vestigial muscle cell lineage. This study examines the number of AChE-positive cells that develop in the anural ascidian Molgula occulta relative to that in the closely related urodele (tailed) species, Molgula oculata. Histochemical assays showed that M. oculata embryos develop 36 to 38 AChE-positive cells, consistent with the number of tail muscle cells expressed in other urodele ascidians. In contrast, M. occulta embryos develop a mean of only 20 AChE-positive cells in their vestigial muscle lineage. Cleavage-arrested embryos of the anural species express AChE only in B-line blastomeres, showing that the vestigial muscle lineage cells are derived from the primary muscle lineage. Less than the expected number of AChE-positive B-line cells develop in cleavage-arrested anural embryos, however, implying that the allocation of primary muscle lineage cells is decreased. Eggs of the anural species can be fertilized with sperm of the urodele species resulting in the development of some larvae that contain a short tail and/or a brain melanocyte, specific features of urodele larvae. The typical urodele number of AChE-positive cells is restored in some of these hybrid embryos. Both primary and secondary muscle lineages are restored because cleavage-arrested hybrid embryos develop more AChE-positive cells in the B-line blastomeres and supernumerary AChE-positive cells in the A-line blastomeres. Hybrid embryos that develop the urodele complement of AChE-positive cells also form a tail and/or a brain melanocyte showing that restoration of muscle lineage cells is coupled to the development of other urodele features. AChE expression occurred in anural embryos with disorganized or dissociated blastomeres, indicating that AChE expression is determined autonomously. It is concluded that an evolutionary change in the allocation of larval muscle lineage cells occurs during development of the anural ascidian M. occulta which can be restored by interspecific hybridization with the urodele ascidian M. oculata.     

Acetylcholinesterase activity in neural crest cells of the early chick embryo

The appearance and distribution of AChE activity in the neural crest cells of the chick embryo were histochemically investigated. Prior to closure of the neural tube, neural crests were not demonstrated and most of the cells constituting the neural plate and the more lateral ectoderm were AChE-negative. With the closure of the neural tube, the neural crests assumed the form of a cell mass in its mid-dorsal portion and AChE activity was demonstrated in some elements of both tube and crests. The neural crest cells beginning to migrate ventrally or laterally were AChE-positive, and some showed intense enzymatic activity. Electron microscopically, the neural crest cells and the cells migrating from the neural crest displayed AChE activity in the cisternae of the nuclear envelope and in a few r-ER profiles, but were morphologically undifferentiated. As assessed by 3H-thymidine autoradiography, these cells possessed the potential to proliferate. These findings indicate that with the formation of the neural tube and neural crest, cells constituting these structures begin to differentiate with respect to AChE activity and that the enzyme appears in the neural crest cells before the onset of neuronal differentiation.     

Biomarker-enhanced assessment of reproductive disorders in Monoporeia affinis exposed to contaminated sediment in the Baltic Sea

Introducing biomarkers into monitoring programs requires understanding of their responses in relation to higher-level biological effects as well as modulating effects of confounding environmental factors. We evaluated relationships between the general toxicity biomarkers (acetylcholinesterase [AChE], lysosomal membrane stability [LMS], oxygen radical absorbance capacity [ORAC]) and reproductive performance (fecundity and embryo aberrations) in the amphipod Monoporeia affinis in the Baltic Sea. To further link biomarker response to contaminant (PCBs, PAHs and metals) levels in the surrounding sediments as well as environmental factors (salinity, bottom depth and total organic carbon in sediments [TOC]), correlation and partial least square regression (PLSR) analyses were applied. The observed contaminants levels were frequently elevated for heavy metals and PAHs, but not PCBs. In the amphipod populations, female ORAC values were positively related to the occurrence of females carrying malformed or membrane-damaged embryos and to the percentage of such embryos in their broods, but also to the fecundity. Female AChE activity was negatively related to the frequency of the membrane-damaged embryos, and positively to the frequency of embryos with arrested development in the broods. Moreover, higher AChE activity and ORAC values in the females occurred at elevated concentrations of metals and PAHs, while there was a negative correlation between embryo ORAC and some PCB congeners. The PLSR models explained over 80% of the variation in the female ORAC and AChE values by variation in contaminant concentrations in combination with environmental variables. Specifically, CB180 and PAM4,9 were identified as negative predictors for ORAC, whereas many PAHs and some metals were positive predictors. The AChE activity was positively related to some metals and negatively to PCBs. In the PLSR models, environmental factors had significant modulating effects, with positive effect of salinity on female ORAC and AChE, and negative effect of TOC on the AChE. The LMS data were less informative, with no apparent relation to any of the contaminants. Linking subcellular responses to the reproduction effects facilitates environmental stress assessment and understanding of the response mechanisms, but also calls for more experimental and field data providing a mechanistic understanding to these linkages.     

Temporospatial localization of acetylcholinesterase activity in the dental epithelium during mouse tooth development

Acetylcholinesterase (AChE), a principal modulator of cholinergic neurotransmission, also has been demonstrated to be involved in the morphogenetic processes of neuronal and non-neuronal tissues. This study shows that AChE exhibits temporospatial activity in the dental epithelium of the developing mouse tooth. To identify the AChE activity in the mouse tooth during development, we performed enzyme histochemistry on the mouse embryos from embryonic day 13 (E13) to E18 and on the incisors and molars of the neonatal mouse at 10 days after birth (P10). In the developing molars of mouse embryos, AChE activity was not found in the dental epithelium at E13 (bud stage). AChE activity first appeared in the developing cervical loops of the enamel organ at E14 (cap stage), but was not found in the enamel knot. At E18 (bell stage), AChE activity was localized in the inner enamel epithelium except the cervical-loop area. In the incisors and molars of neonatal mice (P10), AChE activity was localized in the inner enamel epithelium of the cervical-loop and enamel-free area. Overall, AChE activity was localized in the differentiating dental epithelium while the activity of butyrylcholinesterse, another cholinesterase, was located primarily in the cells of the dental follicle. The results suggest that AChE may play a role in the histo- and cytodifferentiation of dental epithelium during tooth development.     

PRiMA: the membrane anchor of acetylcholinesterase in the brain.

As a tetramer, acetylcholinesterase (AChE) is anchored to the basal lamina of the neuromuscular junction and to the membrane of neuronal synapses. We have previously shown that collagen Q (ColQ) anchors AChE at the neuromuscular junction. We have now cloned the gene PRiMA (proline-rich membrane anchor) encoding the AChE anchor in mammalian brain. We show that PRiMA is able to organize AChE into tetramers and to anchor them at the surface of transfected cells. Furthermore, we demonstrate that AChE is actually anchored in neural cell membranes through its interaction with PRiMA. Finally, we propose that only PRiMA anchors AChE in mammalian brain and muscle cell membranes.     

The marginal zone of the 32-cell amphibian embryo contains all the information required for chordamesoderm development.

The formation of the amphibian organizer is evidenced by the ability of cells of the dorsal marginal zone (DMZ) to self-differentiate to form notochord and to induce the formation of other axial structures from neighboring regions of the embryo. We have attempted to determine when these abilities are acquired in the urodele, Ambystoma mexicanum (axolotl), and in the anuran, Xenopus laevis, by removing the mesodermalizing influence of the vegetal hemisphere at different stages of development and culturing the animal hemisphere isolate. This was possible, even at the 32 and 64-cell stage, through the use of embryos with rare cleavage patterns. Cultured isolates were analyzed for morphological differentiation of mesodermal and neural structures, and for biochemical differentiation of the tissue-specific enzyme, acetylcholinesterase (AChE). Large amounts of mesodermal and neural structures, and normal expression of AChE were found in isolates made as early as the 32-cell stage in both species. Only a small increase in the percentage of isolates developing mesoderm was detected when isolations were made at later cleavage or blastula stages. The amount of mesoderm formed did not depend on the stage of isolation. Mesoderm differentiation was usually limited to the notocord and muscle. The isolates rarely formed pronephros, mesothelium, or mesenchyme, derivatives of ventral mesoderm, during normal development. The results indicate that the marginal zone of the cleavage-stage embryo contains all of the information needed for the formation of the organizer. The formation of dorsal mesoderm does not require subsequent interaction with the cells of the vegetal hemisphere, although the presence of those cells is likely to play a role in normal pattern formation.     

Hormonal modulation of neuronal cells behaviour in vitro

In this study we have investigated the effect of insulin and/or of nerve growth factor (NGF) on enzyme activities of cholinergic neurotransmission, in cultured embryonic rat mesencephali. Our data show that choline-O-acetyltransferase (ChAT) and acetylcholinesterase (AChE) activity display a prominent change in the embryonic brain tissues as a function of time in vitro. The change depends on the age of embryos from which the brain cell cultures have been set up. Namely, ChAT activity increases in the cultures taken from 13-17-day-old embryos as a function of time in vitro. AChE activity shows a striking decrease if the cultures have been set up from the older embryos (17-day-old), while AChE activity increases in the cultures prepared from 13-day-old embryos continuously. Insulin (amount ranging 10-27 micrograms/ml) causes a significant inhibition in the ChAT activity in comparison with the increased enzyme activity measured in control cultures (insulin ranging from 1 to 100 ng). AChE activity of 13-day-old embryos was not influenced by insulin (20-27 micrograms/ml) but the same amount of insulin prevents the decrease of AChE activity in cultured brain cells originating from 17-day-old-embryos. Biochemical studies of NGF treated cultures (30 ng/ml) revealed that nerve growth factor resulted in 5-12-fold increase in specific activity of the cholinergic enzyme, choline acetyltransferase (ChAT). NGF did not influence the AChE activity in cultured brain cells (13-17-day-old).     

Tissue specific expression of the acetylcholinesterase gene in Drosophila melanogaster

Summary Acetylcholinesterase (AChE) is mainly membrane bound in the central nervous system (CNS) of larvae and in the head and thorax of adults of Drosophila melanogaster; it is mostly soluble in the larval carcass, the adult abdomen, similar to that of the embryos (Zador et al. 1986). The enzyme shows the same number of isozymes (four or five) in larvae and adults as in the head of the fly or in embryos (Zador et al. 1986). In the Df(3R)GE26/MKRS stock both the membrane bound and the soluble enzyme are at about half normal levels while in the Df(3R)Ace ^HD1/MKRS stock this is true only for the membrane bound AChE. Therefore the effect of the above deficiencies in larvae and adults is consistent with that in embryos (Zador et al. 1986). In heat-sensitive combinations of certain Ace mutant alleles both the membrane bound and the soluble enzyme has reduced activity.Abbreviations AChE acetylcholinesterase (acetylcholine acetyl hydrolase, EC 3.1.1.7) - BAP 1,5-bis(allyldimethylammonium-phenyl)-pentan-3-one dibromide - CNS central nervous system