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.     

Two types of asymmetric acetylcholinesterase in chick hindlimb muscle: Developmental profiles,in Vivo and in cell culture,and recovery after inactivation

1. We have analyzed the behavior of two types of asymmetric molecular forms (A forms) of acetylcholinesterase (AChE) during development of chick hindlimb muscle, in vivo and in cell culture, and upon irreversible inactivation of peroneal muscle AChE with diisopropylfluorophosphate (DFP) in vivo. 2. In agreement with previous developmental studies on chick muscle, globular forms of AChE (G forms) are predominant in chick hindlimb at early embryonic ages, being gradually replaced by A forms as hatching (and, therefore, onset of locomotion) approaches. Of the two A-form types, AI appears and accumulates significantly earlier than AII, so that A/G and II/I ratios higher than 1 are attained only at about hatching time. 3. Cultures prepared from 11-day chick embryo hindlimb myoblasts express both types of A forms, with a combined activity of 27% of total AChE after 12 days in culture. AI forms appear again earlier and are much more abundant than type II asymmetric species through the life span of cultures. 4. All AChE activity in the peroneal muscle is irreversibly inactivated by injection of DFP in vivo. The recovery of A forms follows the same sequence described for normal development, with a delayed and slower recovery of AII forms as compared with AI. 5. Several hypotheses involving tail polypeptides or tissue target molecules, or posttranslational interconversion, are proposed to help explain the earlier appearance and accumulation of AI forms in chick muscle.     

Ultrastructural localization of acetylcholinesterase in cultured cells. II. Cycloheximide-treated embryo muscle.

The acetylcholinesterase activity (AChE) of cultured chick embryo muscle fibers that remains after the cells have been treated with the protein synthesis inhibitor cycloheximide was examined with cytochemical stains and the electron microscope. AChE activity that decreased rapidly after addition of the inhibitor was associated with enzyme within the cells, and AChE activity that was relatively insensitive to the inhibitor was associated with AChE outside of the cells. The results support the view that there are at least two fractions of AChE in developing muscle fibers, one intracellular and labile, the other extracelullar and stable.     

Interaction of an organophosphate with a peripheral site on acetylcholinesterase

O-Ethyl S-[2-(diisopropylamino)ethyl] methylphosphonothioate (MPT) is an active site directed inhibitor of acetylcholinesterase (AChE). Inhibition of the Electrophorus electricus (G4) enzyme follows classical second-order kinetics. However, inhibition of total mouse skeletal muscle AChE and inhibition of the individual molecular forms from muscle, including the monomeric species, do not proceed as simple irreversible bimolecular reactions. Similarly, complex inhibition kinetics are observed for the purified enzyme from Torpedo californica. AChE can be cross-linked with glutaraldehyde into a semisolid matrix. Under these conditions the abnormal concentration dependence for MPT inhibition is accentuated, and a range of MPT concentrations can be found where inhibition of polymerized AChE is far less than that observed at lower concentrations. Inhibition in certain concentration ranges is partially reversible after removal of all unbound ligand. Thus, there are two different modes of organophosphorus inhibition by MPT: the classical irreversible phosphorylation of the active site and a reversible interaction at a site peripheral to the active center. Propidium, a well-studied peripheral site ligand, can prevent the later interaction. Hence, the second site of MPT interaction with AChE may overlap or be linked to the peripheral anionic site of AChE characterized by the binding of propidium and other peripheral site inhibitors.     

Optical organophosphorus biosensor consisting of acetylcholinesterase/viologen hetero Langmuir–Blodgett film

The fiber-optic biosensor consisting of an acetylcholinesterase (AChE)-immobilized Langmuir–Blodegtt (LB) film was developed to detect organophosphorus compounds in contaminated water. The sensing scheme was based on the decrease of yellow product, o-nitrophenol, from a colorless substrate, o-nitrophenyl acetate, due to the inhibition by organophosphorus compounds on AChE. Absorbance change of the product as the output of enzyme reaction was detected and the light was guided through the optical fibers. The enzyme portion of the sensor system was fabricated by the LB technique for formation of the enzyme film. AChE-immobilized LB film was formed by adsorbing the enzyme molecules onto a viologen monolayer using the electrostatic force. The proposed kinetics for irreversible inhibition of organophosphorus compounds on AChE agreed well with the experimental data. The surface topography of AChE-immobilized LB film was investigated by atomic force microscope (AFM). The immobilized AChE had the maximum activity at pH 7. The proposed biosensor could successfully detect the organophosphorus compounds upto 2 ppm and the response time to steady signal of the sensor was about 10 min.     

Recovery of Acetylcholinesterase in the Diaphragm, Brain, and Plasma of the Rat After Irreversible Inhibition by Soman: A Study of Cytochemical Localization and Molecular Forms of the Enzyme in the Motor End Plate

Abstract Recovery of AChE activity in the motor end plate region and end plate free region of the rat diaphragm was studied after irreversible inhibition by soman. Recovery was slow during the first 2 days and only 4 S and 10 S molecular forms of AChE were present in the end plate region. However, cytochemical evidence indicates that synaptic AChE has already started to accumulate and that the synthesis of AChE in muscle and Schwann cell might even be enhanced. Tubular structures, observed underneath the motor end plate, may serve to transport the enzyme from its sites of synthesis in the sarcoplasmic reticulum. Asymmetric molecular forms of AChE in the end plate region appeared later during recovery and, one week after poisoning, their activity was only about 50% of normal value. The limited ability of newly synthesized AChE to attach to the subcellular structures and, therefore, to be retained in the muscle, may explain the phase of slow recovery. In accordance with this view, AChE activity in brain recovered in a similar way as in muscle, whereas soluble plasma cholinesterases recovered faster, apparently without a slow initial phase.     

Expression of adult fast pattern of acetylcholinesterase molecular forms by mouse satellite cells in culture

The pattern of acetylcholinesterase (AChE) molecular forms, obtained by sucrose gradient sedimentation, was studied at different in vitro developmental stages of myogenic cells isolated from adult mouse skeletal muscle. Only the globular forms were present in rapidly dividing satellite cells during the first days in culture. After myotube formation, a pattern similar to that described in mammalian fast-twitch skeletal muscle was observed. This pattern did not change during the following period in culture (up to 1 month) nor could it be modified by co-culturing with spinal cord motoneurons or by addition of brain-derived extracts. The internal-external localization of AChE molecular forms has been determined by the use of echothiophate iodide, a membrane-impermeant irreversible inhibitor of AChE. Echothiophate-treated cultures showed about 40% of both asymmetric and globular forms localized on the sarcolemma, with their active sites oriented outward. Analysis of culture medium from untreated cultures revealed the presence of both asymmetric and globular forms. When the same analysis was repeated on cultures of myoblasts derived from 16-day-old mouse embryos, the pattern of AChE forms was different. The myotubes derived from these cells exhibit a very small proportion of asymmetric form, which was not released into the medium. This pattern was not further modified during the following days of culture, nor by co-cultures with spinal cord motoneurons or by incubations with brain-derived extracts. Thus, the myotubes derived from myoblasts express in culture a clear phenotypic difference when compared to the corresponding myotubes from satellite cells, supporting the view that these two myogenic cells are endowed with different developmental programs.     

Expression of the A12 form of acetylcholinesterase by developing avian leg muscle cells in vivo and during differentiation in primary cell cultures

The accumulation of the molecular forms of acetylcholinesterase (AChE) has been studied in leg muscles during embryonic chick development and in cell cultures initiated with myoblasts obtained from embryos at different stages of development. The collagen-tailed, A₁₂ form appears in leg muscles as soon as day 5 in ovo. An early excision of the lumbar zone of the neural tube at day 2 1/2 in ovo severely delayed the morphological development. In leg muscles dissected at day 12 in ovo from operated embryos, we found that the total amount of AChE activity and particularly the proportion of A₁₂ form were dramatically reduced.

Muscle cells were grown in vitro in a medium supplemented with fetal calf serum. In these conditions, chick muscle cells unequivocally synthesize the A₁₂ form when they originated from muscles which accumulated this form in vivo. In contrast, myoblasts obtained from 5-day old embryo leg muscles did not produce the A₁₂ form either in aneural cultures or in the presence of nerve cells. In relation with previous observations concerning chick myogenesis, we discuss the possibility that this difference reflects the existence of two types of myoblasts. This hypothesis would also explain the results of cocultures performed with nerve cells and normal or demedullated leg muscle myoblasts.     

Human myotube differentiation in vitro in different culture conditions

Human muscle cells derived from satellite cells, maintained in standard tissue culture conditions, do not differentiate as rapidly or as completely as myoblasts from other species (chicken, rat, mouse). In an attempt to improve myogenesis, we studied the effects of modifying the culture media and of coculturing muscle with nerve cells, using myoblasts grown in standard culture media as the basis for comparison. Myogenesis was measured by fusion index, creatine kinase (CK) activity; acetylcholinesterase (AChE) activity (total and molecular forms); and the number of acetylcholine receptors (AChR). Modification of culture media accelerated fusion of myoblasts, but the cell density decreased and myotubes were unable to survive for long periods. In contrast, coculturing muscle with nerve cells increased both cell density and the number of myotubes. CK, AChE and AChR increased in the presence of defined media. In the nerve-muscle cocultures the increase was less marked. Manipulating culture conditions modified the molecular forms of AChE. Only a (4 + 6.5) S peak was present in control cultures, but a 10S peak appeared in defined media. The 16S form was detected only in nerve-muscle cocultures. This study shows that fusion of human myoblasts and differentiation of myotubes in tissue culture can be accelerated by removal of serum macromolecules. Further differentiation of myotubes was achieved only in the nerve-muscle cocultures.     

Phenotypic modulation of chick embryo muscle cells in a suspension culture

Three-dimensional aggregates are formed in the suspension culture by myoblasts of the chick embryo femoral muscle. Cells present in these aggregates undergo mitotic divisions just as in a monolayer; thereafter they fuse with the formation of myosimplasts. Further stages of myogenesis are impaired under the conditions of the suspension culture. This was manifested in the formation of atypical, massive spherical or vesicle-like thick-walled myosimplasts with dozens or hundreds of randomly clustered nuclei. After the replating and attachment to a glass surface myosimplasts undergo gladual elongation and differentiate into muscle fibers. Thus the attachment to the artificial solid support is a necessary prerequisite for the completion of morphogenesis in vitro.     

The Development and Distribution of Cholinesterases in Cultured Skeletal Muscle with and without Nerve

Cholinesterase development was studied biochemically and histochemically in monolayer cultures of muscle cells from 10 day chick embryo leg muscle. Cholinesterase activity was low in myoblasts but increased rapidly after cell fusion and myotube formation; activity was distributed unevenly throughout myotubes, older fibres having some small areas of intense activity. Total Cholinesterase activity increased over the 10 day culture period while soluble activity reached a plateau after 4 days and was between 30–40% of the total. Butyrylcholines-terase activity did not change significantly during the period of study, comprising about 12% of the total Cholinesterase activity at 10 days. The possible effects on Cholinesterase development of combining muscle with dissociated spinal cord cells and with spinal cord explants, and of growing muscle in medium from which non-specific neural factors had been removed, was examined. No evidence was found for a nerve trophic effect on the amount or on the localization of muscle Cholinesterases.     

Recovery of acetylcholinesterase and of its multiple molecular forms in motor end-plate-free and motor end-plate-rich regions of mouse striated muscle, after irreversible inactivation by an organophosphorus compound (methyl-phosphorothiolate derivative)

Most of mouse diaphragm muscle acetylcholinesterase (AChE) is irreversibly inhibited after a single intraperitoneal injection of a methyl-phosphorothiolate derivative (MPT), an organophosphorus compound which phosphorylates the active site. The muscle recovers its AChE (de novo synthesis) and we studied the time course of reappearance of AChE and its multiple active molecular forms. After inhibition, there is an initial (3 to 15 hr) rapid recovery of total AChE (which evolves from 20-28% to 50-60% of the control values), followed by a slow phase of AChE return. After 3 days, the recovery is still incomplete (reaching 70-80% of control values). Among the main molecular forms present in diaphragm muscle (16 S, 10 S and 4 S, accompanied by minor components), the 16 S and 10 S forms are the most sensitive to MPT treatment. During the rapid initial phase of AChE recovery, the absolute rate of recovery of the 4 S form is faster than for the other forms with a correspondingly much higher relative proportion to total AChE. These observations are consistent with the hypothesized precursor role of the 4 S form. The 16 S form, which is found concentrated in the motor end-plate (MEP)-rich regions and in low amounts in MEP-free regions, is similarly partially recovered in both regions, suggesting that there is 16 S biosynthesis not only in the MEP-rich regions but also in the MEP-free regions.     

Studies on acetylcholine sensor and its analytical application based on the inhibition of cholinesterase

Acetylcholine esterase electrodes, based on glass, Pd/PdO and Ir/IrO₂ electrodes as pH sensor, using the immobilized acetylcholine esterase in acrylamide-methacrylamide hydrazides prepolymer are reported and compared. New data on the analysis of nicotine, fluoride ion, and some organophosphorus compounds are reported using the present AChE sensor based on the inhibition of the immobilized acetylcholine esterase. Reactivation of immobilized AChE after inhibition with reversible inhibitor, i.e. nicotine and fluoride ion is carried out using a mixture of working buffer and acetylcholine, whereas reactivation after inhibition with irreversible inhibitor, i.e. organophosphorus compounds is carried out using a mixture of acetylcholine and pyridine-2-aldoxime methiodide (PAM). The detection limits for the nicotine and fluoride ion are found to be 10⁻⁵M whereas for paraoxon, methyl parathion and malathion are found to be 10⁻⁹ M and 10⁻¹⁰ M.     

Comparison Between the Effects of Botulinum Toxin-Induced Paralysis and Denervation on Molecular Forms of Acetylcholinesterase in Muscles

Abstract: Velocity sedimentation analysis of acetylcholinesterase (AChE) molecular forms in the fast extensor digitorum longus muscle and in the slow soleus muscle of the rat was carried out on days 4, 8, and 14 after induction of muscle paralysis by botulinum toxin type A (BoTx). The results were compared with those observed after muscle denervation. In addition, the ability of BoTx-paralyzed muscles to resynthesize AChE was studied after irreversible inhibition of the preexistent enzyme by diisopropyl phosphorofluoridate. Major differences were observed between the effects of BoTx treatment and nerve section on AChE in the junctional region of the muscles. A precipitous drop in content of the asymmetric A12 AChE form was observed after denervation, whereas its decrease was much slower and less extensive in the BoTx-paralyzed muscles. Recovery of junctional AChE and of its A12 form after irreversible inhibition of the preexistent AChE in BoTx-paralyzed muscles was nevertheless very slow. It seems that a greater part of the junctional A12 AChE form pertains to a fraction with a very slow turnover that is rapidly degraded after denervation but not after BoTx-produced muscle paralysis. The postdenervation decrease in content of junctional A12 AChE is therefore not primarily due to muscle inactivity. The extrajunctional molecular forms of AChE seem to be regulated mostly by muscle activity because they undergo virtually identical changes both after denervation and BoTx paralysis. The differences observed in this respect between the fast and slow muscles after their inactivation must be intrinsic to muscles.     

Depression of acetylcholinesterase synthesis following transient cerebral ischemia in rat: pharmacohistochemical and biochemical investigation

The effect of transient cerebral ischemia on acetylcholinesterase (AChE) synthesis was studied in rats by a modified pharmacohistochemical method. The procedure involved in vivo irreversible inhibition of AChE by administration of the inhibitor diisopropyl fluorophosphate (DFP; 1.2 mg/kg b.w., i.m.) 1 h before 30 min forebrain ischemia (the four-vessel occlusion model). At the onset of ischemia, 70-75% of AChE was inhibited in the brain. Recirculation was followed by histochemical and biochemical investigations of newly synthesized AChE in the striatum, septum, cortex and hippocampus. Control sham-operated animals were treated with the same dose of DFP. For correlation, rats not treated with DFP were subjected to the same ischemic procedures and investigated simultaneously. In these rats, significant decrease in AChE activity was found in the striatum, septum and hippocampus during 24 h recirculation. In DFP treated rats, ischemia markedly depressed resynthesis of AChE; after 4 h recirculation, AChE activity was decreased by 45-60% in all investigated areas in comparison with controls and the AChE histochemistry showed only slightly stained neurons in the striatum and septum. Twenty-four hours after ischemia, these neurons were densely stained and the increase in AChE activity indicated a partial recovery of the enzyme synthesis. These results suggest that the depression of AChE synthesis after forebrain ischemia is probably transient, not accompanied by cholinergic neuron degeneration.     

PROPERTIES OF THE EXTERNAL ACETYLCHOLINESTERASE IN GUINEA-PIG IRIS

Abstract— The acetylcholinesterase (AChE) of intact iris, the so-called external AChE, differs in several respects from the AChE in an homogenate of iris, called the total AChE. Maximum enzyme activities of the external and total AChE were obtained with an ACh concentration of 10 and 1.3 m m , respectively. The total AChE exhibited substrate inhibition at high substrate concentrations, whereas the external enzyme did not exhibit substrate inhibition in the range studied. The external AChE activity, when measured at 1.3 m m -ACh. accounted only for 12% of the total enzyme activity. After irreversible inhibition of AChE with diisopropylfluorophosphate (DFP) or methylisocyclopentylfluorophosphate (soman) the external AChE recovered to almost normal values after 48 h, whereas only 30% of the total AChE recovered during this period. Pupillographic studies after inhibition with DFP demonstrated that pupillary diameter had reached normal size after 24 h.
Destruction of the cholinergic input to iris reduced the total AChE activity by 40%, but did not alter the external AChE activity nor its rate of recovery after DFP inhibition. The specific activities of total AChE and total choline acetyltransferase were significantly higher in the sphincter than in the dilator muscle. After such denervation of iris the greatest reduction in total AChE and choline acetyltransferase were found in the sphincter region. After treatment with DFP the total AChE was inhibited to the same extent and recovered at the same rate in both regions.
After extraction of AChE from iris with various salt solutions and detergents, the particulate enzyme recovered faster than the soluble enzyme from DFP inhibition.     

Molecular forms and localization of acetylcholinesterase and nonspecific cholinesterase in regenerating skeletal muscles

Molecular forms and histochemical localization of acetylcholinesterase and nonspecific cholinesterase were analysed in muscle regenerates obtained from rat EDL and soleus muscles after ischaemic-toxic degeneration and irreversible inhibition of preexistent enzymes. Regenerating myotubes and myofibres produce the 16S AChE form in the absence of innervation. The 10S AChE form prevails over 4S form with maturation into striated fibres. Although the patterns of AChE molecular forms in normal EDL and soleus muscles differ significantly no such differences were observed in noninnervated regenerates from both muscles. Two types of focal accumulation of AChE appear on the sarcolemma of regenerating muscles: first, in places of former motor endplates and, second, in extrajunctional regions. The 4S form of nonspecific cholinesterase is prevailing in regenerating myotubes whereas its asymmetric forms or focal accumulations could not be identified reliably. The satellite cells which survive after muscle degeneration probably originate from some type of late myoblasts and transmit the information concerning the ability to synthesize the asymmetric AChE forms and to focally accumulate AChE to regenerating muscle cells. Synaptic basal lamina from former motor endplates may locally induce AChE accumulations in regenerating muscles.Special Issue Dedicated to Dr. Abel Lajtha.     

A Globular, Not Asymmetric, Form of Acetylcholinesterase Is Expressed in Chick Motor Neurons: Down-Regulation Toward Maturity and After Denervation

Abstract: In vertebrate neuromuscular junctions, the postsynaptic specializations include the accumulation of acetylcholinesterase (AChE) at the synaptic basal lamina and the muscle fiber. Several lines of evidence indicate that the presynaptic motor neuron is able to synthesize and secrete AChE at the neuromuscular junctions. By using anti-AChE catalytic subunit, anti-butyrylcholinesterase (BuChE) catalytic subunit, and anti-AChE collagenous tail monoclonal antibodies, we demonstrated that the motor neurons of chick spinal cord expressed AChE in vivo and the predominant AChE was the globular form of the enzyme. Neither asymmetric AChE nor BuChE was detected in the motor neurons. The molecular mass of AChE catalytic subunit in the motor neuron was ∼105 kDa, which was similar to that of the globular enzyme from low-salt extracts of muscle; both of them were ∼5 kDa smaller than the asymmetric AChE from high-salt extracts of muscle. The level of AChE expression in the motor neurons decreased, as found by immunochemical and enzymatic analysis, during the different stages of the chick's development and after nerve lesion. Thus, the AChE activity at the neuromuscular junctions that is contributed by the presynaptic motor neurons is primarily the globular, not the asymmetric, form of the enzyme, and these contributions decreased toward maturity and after denervation.     

Ultrastructural localization of acetylcholinesterase in cultured cells. III. DFP treated embryo muscle

Brief treatment with 10(-4)M diisopropylfluorophosphate (DEP) irreversibly inactivates acetylcholinesterase (E.C.3.1.1.7; acetylcholine hydrolase) (AChE) activity in 10 day old chick embryonic muscle cultures. Electron microscopic cytochemistry was employed to follow the distribution of new AChE during recovery from DEP treatment. In normal 10 day cultures of embryo pectoralis muscles AChE is localized in the nuclear envelope, perinuclear sarcoplasm, sarcotubular system, subsurface vesicles and bound outside the cells. Immediately after DFP treatment AChE activity is absent in large myotubes. Within 15 min, activity is randomly present in small amounts in the sarcotubular system and nuclear envelope. There is a dramatic increase in activitv in the nuclear envelope during the 1st hr of recovery, and connections between the nuclear envelope and sarcotubular system are often seen. The next few hr of recovery show increased AChE activity. By 4 hr activity approaches that of controls. Six to 8 hr after treatment, AChE activity can be detected spectrophotometrically in the medium and can be seen bound outside the cells with the electron microscope. The spatial and temporal patterns of AChE activity demonstrate that the recovery of AChE and its mobilization and release from DFP-treated cells are not governed solely by the levels attained by the enzyme in the cultured embryo muscle.     

Biochemical and cytochemical evidence indicates that coated vesicles in chick embryo myotubes contain newly synthesized acetylcholinesterase

We have isolated highly purified coated vesicles from 17-d-old chick embryo skeletal muscle. These isolated coated vesicles contain acetylcholinesterase (AChE) in a latent, membrane-protected form as demonstrated enzymatically and morphologically using the Karnovsky and Roots histochemical procedure (J. Histochem. Cytochem., 1964, 12:219- 221). By the use of appropriate inhibitors the cholinesterase activity can be shown to be specific for acetylcholine. It also can be concluded that most of the AChE represents soluble enzyme since it is rendered soluble by repeated freeze-thaw cycles. To determine the origin of the coated vesicle-associated AChE, we have isolated coated vesicles from cultured chick embryo myotubes which have been treated with diisopropylfluorophosphate, an essentially irreversible inhibitor of both intra- and extracellular AChE, and have been allowed to recover for 3 h. This time is not enough to allow any newly synthesized AChE to be secreted. These coated vesicles also contain predominantly soluble AChE. These data are compatible with the hypothesis that coated vesicles are important intermediates in the intracellular transport of newly synthesized AChE.